Formulations containing labels for medical diagnostics

ABSTRACT

Systems, techniques and methods for estimating the metabolic state or flux, e.g., the body energy state (“BES”) of a patient, are disclosed. The BES provides deep insight into the nutritional needs of the patient, thus allowing for a sort of exquisite glycemic control with regard to the patient. The invention discloses systems and methods for estimating fractional gluconeogenesis, which is the % of glucose production that comes from gluconeogenesis (“GNG”), as opposed to glycogenolysis (“GLY”), the other form of glucose production. Nutritional formulations, materials, cocktails and methods for feeding patients by parenteral and other means are disclosed. The amount, type and rate of such nutritional feeding are typically based upon the above estimating. The invention discloses formulations that contain labels, such as deuterium, for medical diagnostics, such as for estimating BES and fractional gluconeogenesis. The invention is suitable for any sort of patient, including those who are injured, such as with traumatic brain injury, ill, or have other conditions that stress the metabolic system.

APPLICATION PRIORITY DATA

The current patent application claims priority to U.S. provisional patent application 61/795,819 filed on Oct. 25, 2012 by Horning and Brooks and is related to U.S. patent application Ser. No. 13/903,929 filed on May 28, 2013 by Horning and Brooks, titled “FORMULATIONS AND METHODS TO PROVIDE NUTRITION TO HUMAN AND OTHER PATIENTS” and Ser. No. 13/903,936 filed on May 28, 2013 by Horning and Brooks, titled “SYSTEMS AND METHODS TO ESTIMATE NUTRITIONAL NEEDS OF HUMAN AND OTHER PATIENTS”, which are incorporated by reference in their entirety.

FIELD OF THE INVENTION

The present disclosure generally relates to the field of medical treatment. More specifically, the invention presents systems and methods to ascertain the metabolic state and nutritional needs of a patient, which can be thought of as the body energy state (“BES”) of the patient. Assessment of the BES of the patient is critical information to treat and nourish (feed) the patient appropriately. Such assessment is based on ongoing and dynamic estimates of the biomarker fractional gluconeogenesis, which is the % of body glucose production that comes from gluconeogenesis. Methods, systems and materials for patient nutritional treatment and feeding based on estimation of this biomarker are also provided.

BACKGROUND OF THE INVENTION

Glucose is a basic fuel of the human body (as well as of many other organisms) and is delivered throughout the body through the blood. The rate of glucose production, also referred to as glucose rate of appearance and glucose Ra, is about 2-3 mg/min/kg of body weight in a healthy person while at rest, and can be as high as 8 mg/min/kg or more under stress such as exercise or illness. Pyruvate and lactate, which are both gluconeogenic precursors and products of glucose catabolism, are also basic fuels of the human body and other organisms.

Glucose, a six-carbon (hexose) sugar, is an essential fuel energy source for several vitally important organs and tissues in the body, including the brain and nerves that require a continuous glucose supply, including after injury. Not surprisingly, glucose is an important and tightly regulated metabolite.

Glucose Ra should not be confused with blood concentration of glucose, also called [glucose]. The latter is a simple measure of the total amount of glucose in the blood, as opposed to the rate of production. The [glucose] is a common measurement taken from a blood samples, as in standard doctor office visits and home diabetes diagnostics. This value can vary significantly in resting individuals, but generally averages about 90-100 mg/dl blood or 5.5 mM. Physiologically, glucose can appear in the blood of a person by three major means: delivery from ingested carbohydrate-containing foods, hepatic glycogenolysis (“GLY”), and gluconeogenesis (“GNG”) (hepatic and renal). The recommended dietary allowance for carbohydrate-containing foods is about 130 g/day, a value determined to be the minimal daily brain glucose requirement (8) (note that non-patent literature citations are made as numbers in parentheses, and the corresponding references are listed at the end of this specification). Hence, dietary carbohydrate and total nutrient inadequacy will reflexively cause increased GLY and GNG to maintain glucose requirements for the brain, other tissues with high glucose needs (nerves, red blood cells, kidneys) and the body in general.

Glucose production occurs by GLY and GNG. It is generally better if the majority of glucose production is from GLY. This is because GLY is an efficient process of glucose production, in that it is simple breakdown of glycogen, a glucose polymer stored mainly in the muscles, liver and kidneys. Normally, at rest, in a nourished state, most glucose is produced by GLY (typically over 75%). This number can decrease under stress such as exercise or illness, as the body needs to produce more glucose than can be provided by GLY.

Gluconeogenesis (“GNG”) describes essentially all pathways for producing glucose other than glycogenolysis (“GLY”). GNG produces glucose from carbon substrates such as pyruvate, lactate, glycerol, and gluconeogenic amino acids, among others. These can be termed GNG precursors. GNG is less efficient than GLY in terms of glucose produced per unit of stored energy because of the more complex pathways needed to produce it. Since it is less efficient than GLY, it is generally not preferred by the body, but can be used to produce glucose as needed. GNG is less efficient than GLY in other ways as well. The work of raising a GNG precursor to the level of glucose 6-phosphate and glucose requires significant energy input, and important body constituents such as lean body mass, muscle are often degraded to provide precursor materials for the process. GNG also may be used to access glycogen stored elsewhere in the body instead of direct conversion of that glycogen to glucose.

The current art in the measurement of metabolic state and treatment has at least two significant categories of problems. One is that no biomarker measurements, either alone or in combination, are used in the current art to give an accurate picture of the overall BES of a patient. To the degree that measurements are made in the current art, such as with [glucose], they are inadequate indicators of the BES.

The biomarker [glucose], is well known in the art and simple to assess from a blood test. While a large shift (either low or high) in [glucose] can be cause for concern and inform the type of feeding the patient receives, it does not provide a good indicator of the BES of a patient, especially within its typical ranges. Indeed, the maintenance of blood glucose homeostasis is a top physiological priority, and there are diverse and redundant body mechanisms to maintain blood [glucose]. Thus a normal [glucose] may belie metabolic stresses that are going on, with the body working very hard to maintain [glucose]. Among those mechanisms are GNG, a critically important process about which the blood [glucose] measurement provides no direct information.

Another biomarker, glucose rate of appearance (“Ra”), gives only a slightly better indicator of the BES of the patient. A high glucose Ra, for example, indicates that the patient may be experiencing a stress (such as injury, exercise or starvation) that has induced a high glucose production. While this is a somewhat useful, there is need for a biomarker that is a more precise indicator of BES. In addition, determination of glucose Ra is complex, time consuming and costly. It requires labeled glucose to be given to the patient, typically glucose with deuterium (typically noted as simply D or ²H as opposed to merely H, hydrogen), or carbon 13 (¹³C), and comparison of labeled and non-labeled glucose (the latter produced by the glucose pathways) to determine Ra (80).

The complex, costly and time-consuming process of determining glucose Ra with stable isotopes of H (typically deuterium) or ¹³C-glucose is well described in the literature (2, 26, 55). It is typically done as follows. Control subjects or patients receive a primed continuous infusion of [6,6⁻²H]glucose, i.e., D₂-glucose, glucose with two deuteriums on carbon number 6 (C-6) diluted in 0.9% sterile saline and tested for pyrogenicity and sterility prior to infusion. To hasten achievement of a constant blood isotopic enrichment, a priming bolus of perhaps about 125 times the continuous per minute infusion rate, or about 250 mg D₂-glucose, is infused over several min prior to commencement of a continuous tracer infusion of 2.0 mg·min⁻¹D₂-glucose. In this manner, isotopic equilibration in the blood can be achieved in 60-90 min (about half the time to isotopic equilibration in blood if a priming tracer dose is not given).

To verify when isotopic equilibration has been achieved, several ml of blood is drawn serially. Verification can be done by mixing in several volumes of 6-8% perchloric acid (“PCA”), and the deproteinized supernatant analyzed by means of forming a penta-acetate derivative followed by analysis using gas chromatography/mass spectrometry (“GC/MS”).

For simultaneous concentration analysis, known amounts of a labeled internal standard, such as uniformly labeled glucose, where each carbon of the glucose is labeled, by for example, the carbon 13 isotope, thus noted [U-¹³C]glucose, is used. The glucose molecule thus has an increased mass of about 6 atomic units (“au”) (m+6). This labeled glucose is added to the supernatant of control subject or patient samples collected in perchloric acid. To separate glucose, samples are neutralized with 2N KOH and transferred to cation resin, ion exchange columns such as 50W-X8 (from Bio-Rad Laboratories). Glucose is eluted first with doubly deionized H₂O (the anions, and cations, by contrast, are retained on the column).

The glucose ion-exchange effluent is reduced by lyophilization and derivatized by resuspending the lyophilized sample in a small amount (e.g., 1 ml) of methanol, a small amount [e.g., 200 microliter (μl)] is transferred to a 2 ml microreaction vial and dried under N₂ gas. A small amount (e.g., 100 μl) of a 2:1 acetic anhydride-pyridine solution is added to each sample vial and heated at 60° C. for 10 min. Samples are again dried under N₂ gas, resuspended in a small amount (e.g., 200 μl) of ethyl acetate, and transferred to micro vials for analysis.

Glucose isotopic enrichment (“IE”) is determined by GC/MS, for instance with a GC model 6890 series and MS model 5973N, from Agilent Technologies) of the penta-acetate derivative, where methane is used for selected ion monitoring of mass-to-charge ratios (m/z) 331 (non-labeled glucose), 332 (M+1 isotopomer, [1-¹³C]glucose), 333 (M+2 isotopomer, D₂-glucose), and 337 (M+6 isotopomer, [U-¹³C]glucose, the internal standard). Whole blood glucose concentration is determined by abundance ratios of 331/337. Selected ion abundances are compared against external standard curves for calculation of concentration and isotopic enrichment.

Therefore there is a need in the art for a biomarker that is a good indicator, by itself, of BES, as well as simple and effective methods of estimating that biomarker.

SUMMARY OF THE INVENTION

The invention presents systems and methods to ascertain the metabolic state and nutritional needs of a patient. Such assessment is based on ongoing and dynamic estimates of the biomarker fractional gluconeogenesis, which is the % of body glucose production that comes from gluconeogenesis. Methods, systems and materials for patient nutritional treatment and feeding based on estimation of this biomarker are also provided. The invention includes, but is not limited to the following, with some variation.

According to an embodiment of the present disclosure, the invention provides a method for estimating the fractional gluconeogenesis of a patient, administering a label to the patient, taking a blood sample from the patient, analyzing glucose or a glucose derivative from the blood sample, obtaining a value for fractional gluconeogenesis based on abundance from one or more mass spectra, obtaining a value for fractional gluconeogenesis plus glycogenolysis from one or more mass spectra, and estimating fractional gluconeogenesis.

According to an embodiment of the present disclosure, the invention provides a method for providing nutritional support to a patient, including administering a label to the patient, taking a blood sample from the patient, analyzing glucose or a glucose derivative from the blood sample, obtaining a value for fractional gluconeogenesis based on abundance from one or more mass spectra, obtaining a value for fractional gluconeogenesis plus glycogenolysis from one or more mass spectra, using the value to create to estimate fractional gluconeogenesis, and administering a parenteral nutritive formulation to the patient based upon the fractional gluconeogenesis estimate. The label may be deuterium.

According to an embodiment of the present disclosure, the invention provides a method for estimating the fractional gluconeogenesis of a patient, the method including, administering a label to the patient, estimating the fraction of body water that has been labeled, using this estimate to create a baseline for the amount of total glucose production, estimating an amount of glucose production only from gluconeogenesis by measuring the label, and estimating the patient's fractional gluconeogenesis.

The methods can include a water labeled with deuterium, wherein less than about 1% of the body water is labeled, wherein the body water is labeled with an initial bolus, wherein the body water is continually labeled by ongoing infusion of labeled water, wherein the glucose derivative is a penta-acetate glucose molecule with molecular weight of about 390, wherein part of the estimation is based on the abundance of the label on one or more of glucose carbons 1, 3, 4, 5, 6, wherein part of the estimation is based on the abundance of the label on glucose carbon 2, wherein glucose Ra is estimated to further provide an estimate of absolute rate of GNG, and using a correction factor to correct for the fraction of the molecule that exists in a state that includes the label. The method provides for molecule analysis in a gas chromatograph mass spectrometer. The method provides, upon estimating the fractional gluconeogenesis, the patient is administered a parenteral nutritive formulation, wherein the formulation may contain MCC or GNG precursor or both, pyruvate or lactate or both, wherein the formulation is administered or increased if the estimated fractional GNG is above about 25% or 35%, wherein the formulation is stopped or decreased if the estimated fractional GNG is below about 15% or 20%.

According to an embodiment of the present disclosure, the invention provides a parenteral nutritive formulation for feeding a patient to decrease or stabilize fractional gluconeogenesis, including water and MCC or GNG precursor or both. It also provides a parenteral nutritive formulation for feeding a patient with injury or illness, including water and MCC or GNG precursor or both. It also provides parenteral nutritive formulation for feeding a patient to decrease or stabilize fractional gluconeogenesis, the formulation including water and lactate or pyruvate or both, and one or more salts, wherein the formulation has an osmolality less than about 310 mOsm.

The formulations may also include one or more salts, one or more of Na⁺, K⁺, Ca⁺⁺, Mg⁺⁺, and H₂PO₄ ⁻ , a label such as deuterium, have an osmolality of less than about 310 mOsm, where one of the MCCs or GNGs is lactate or pyruvate or both, where one of the MCCs or GNGs is an amino acid where one of the MCCs or GNGs is a GNG precursor that naturally occurs in the body, where one of the MCCs or GNGs is a compound that does not naturally occur in the body but that can be used as a GNG precursor, where one of the MCCs or GNGs is glycerol or glycerol tri-lactate. The formulation may be administered at a rate of about 3 mg/kg/min, where kg is kg of patient body weight and 3 mg is the amount of MCC or GNG in the formulation, may be administered at a rate of about 50 micro moles per kg of body weight per minute (μMoles/kg/min), where kg is kg of patient body weight and 50 μM is the amount of MCC or GNG in the formulation, administered or increased if estimated fractional GNG is above about 25% or 35%, or decreased or stopped if estimate of fractional gluconeogenesis is below about 20% or 15%.

The formulations may include a label such as deuterium and one or more salts. They may contain or more of the following: Na+, K⁺, Ca⁺⁺, Mg⁺⁺, and H₂PO₄ ⁻ . They may have Na⁺, K⁺, Ca⁺⁺, Mg⁺⁺, and H₂PO₄ ⁻ provided in the ratio of about 145, 4, 2.5, 1.5, and 1.0 respectively. They may have MCC or GNG precursor or both. The formulation may have an osmolality of less than about 310 mOsm. The formulation may have an MCCs or GNGs that is lactate or pyruvate or both, an amino acid, a GNG precursor that naturally occurs in the body, a compound that does not naturally occur in the body but that can be used as a GNG precursor, glycerol tri-lactate or arginyl lactate. The formulation may be administered at a rate of about 3 mg/kg/min, where kg is kg of patient body weight and 3 mg is the amount of MCC or GNG precursor in the formulation and may be administered or increased if estimated fractional GNG is above about 25% or 35%, or decreased or stopped if estimate of fractional gluconeogenesis is below about 20% or 15%. The formulations may be parenteral, used to estimate fractional GNG, used to stabilize or decrease fractional GNG. The label may be incorporated into glucose. The label may be differentially incorporated into glucose depending on whether it is incorporated via the gluconeogenesis pathway or via the glycogenolysis pathway.

The nutritive formulations may include deuterium, lactate or pyruvate or both, and one or more salts, may have an osmolality of less than about 310 mOsm, may have one more of the following: Na+, K⁺, Ca⁺⁺, Mg⁺⁺, and H₂PO₄ ⁻ , may be parenteral. The nutritive formulation may be used to decrease or stabilize fractional gluconeogenesis, and include deuterium, lactate or pyruvate or both, and one or more salts, may have an osmolality of less than about 310 mOsm, and may have one more of the following: Na⁺, K⁺, Ca⁺⁺, Mg⁺⁺, and H₂PO₄ ⁻ .

In all of the systems and methods, various labels may be used, including deuterium, such as in deuterium oxide (water), and sometimes at a concentration of less than about 1% of the water. The formulations may be enteral or parenteral.

BRIEF DESCRIPTION OF THE DRAWINGS

The described techniques and mechanisms, together with other features, embodiments, and advantages of the present disclosure, may best be understood by reference to the following description taken in conjunction with the accompanying drawings, which illustrate various embodiments of the present techniques and mechanisms. In the drawings, structural elements having the same or similar functions are denoted by like reference numerals.

FIG. 1 is a standard chemical representation/illustration of the molecule glucose, approximate molecular weight (“MW”) 180, in the biologically dominant alpha-D-glucose confirmation.

FIG. 2 is a standard chemical representation/illustration of the molecule glucose, with all seven hydrogens replaced with deuteriums (as labels).

FIG. 3 shows the penta-acetate glucose derivative, approximate MW 390, that is part of the mass spectra analysis method, in a preferred embodiment of the invention.

FIG. 4 shows a fragment of the penta-acetate glucose derivative with all of the hydrogens of interest still on the molecule, approximate MW 331, as well as the same molecule with different isotopes (MW 332, etc.)

FIG. 5 shows a fragment of the penta-acetate glucose derivative, approximate MW 271, as well as the same molecule with different isotopes (MW 272, etc.)

FIG. 6 shows another fragment of the penta-acetate glucose derivative, approximate MW 169, as well as the same molecule with different isotopes (MW 170, etc.)

FIG. 7 shows a schematic mass spectrum focusing on the MW 331 and related ions.

FIG. 8 shows a schematic mass spectrum focusing on the MW 169 and related ions.

FIG. 9 shows a schematic mass spectrum showing the MW 169, 271, 331 and related ions.

FIG. 10 shows an actual GC/MS spectrum of the current invention, showing peaks corresponding to the selected ion monitoring (“SIM”) of the MW 331 and 332 ions, where the intensity of the signal is calculated by integrating the areas under the peaks.

DETAILED DESCRIPTION OF THE INVENTION

Gluconeogenesis (“GNG”)

That superior biomarker for assessing the BES of a patient, as disclosed in the present invention, is fractional GNG, that is, the % of total glucose production that comes from GNG.

Various embodiments of the present disclosure provide systems and mechanisms for estimating fractional GNG in a patient. The disclosed invention includes systems and methods for determining the nutrition state and needs of the patient also based on the absolute rate of GNG and the rate of glucose appearance, among other measures. It also includes systems and methods for treating patients using nutritive formulations as disclosed. In a preferred embodiment of the invention, we estimate fractional GNG in a patient, and use this to prescribe the rates of parenteral and enteral energy substrate administration to support patient recovery. Some of the expected benefits of this treatment are an increased healing rate and decreased hospitalization time. Importantly, in some patients the results of our invention may make the difference between poor versus good recovery, and in other patients, the difference between life and death. The course of discovery to use fractional GNG as a biomarker of BES and needs for energy substrate nutrition is described here.

Inspiration for the invention arose in part from the inventors' cumulative professional experiences in public service, education, and consultation in industry and metabolic research in exercise physiology. In particular, metabolic stresses such as the oxygen-limited condition of high altitude, cigarette smoking, and the personal experience of one inventor, Michael Horning (“MAH”) observing the metabolic effects of a traumatic brain injury (“TBI”) to a family member served to help the inventors conceive and reduce the invention to practice.

Note that in the current art, the term glycemia is loosely used to mean the state of the body and blood glucose, in particular [glucose]. But the current invention takes the term and makes it much more precise, by describing underlying mechanisms of glycemic control such as GNG and fractional GNG. The term “tight” glycemic control is sometimes used loosely in the current art to mean a more nuanced approach to control of glucose, but is also not very precise. The current invention provides systems and methods for a sort of “exquisite” glycemic control that is vastly superior at estimating the patient's BES and meeting the patient's nutritional needs. In 2006, Ruthe Horning (“RH”), mother of MAH, was struck by a car while riding her bicycle in Pacific Grove, Calif. She suffered a severe traumatic brain injury, and was rushed into emergency surgery for her first craniectomy. Later that night she received a second emergency craniectomy (a bilateral craniectomy) to help reduce the swelling created by the subdural hematoma resulting from the injury to her brain, and her chances of survival (or good recovery) were uncertain. Over the next several weeks of visiting RH in the intensive care unit (“ICU”) MAH made many observations concerning the metabolic status of his mother including increased heart rate and temperature while she was in a coma.

From experience and training in science, MAH believed by gross observation of RH's condition and vital signs, that his mother's metabolic state was not that of a resting person, but rather her metabolism was more like that of an exercising person. Coupled with those observations MAH also noted that RH's recovery accelerated when she was eventually given enteral nutrition, at his urging. This nutritional source resulted in a marked improvement and she gained strength and mental faculties almost immediately.

RH was in serious need of nutritional support, but was underfed as the result of state of the art treatment. Many months later RH regained enough mental faculties to start to comprehend the enormity of the accident and her injuries, and MAH made a commitment to her that he would find a better treatment for injured patients. Thus a compelling need was articulated that led to a path of discovery of the current invention. The need, in part, was for one or more key biomarkers of BES, methods for measuring these biomarkers, and nutritional treatment methods and formulations based on such measurements.

Over the years, the two inventors began exploring for the particular biomarkers that could be used for BES assessment and treatment. The inventors were looking for an ideal diagnostic method to use in evaluating metabolic state and nutritional needs, or BES, of an ill or injured hospitalized human or animal patient. Over time, based on many studies and empirical observation, it became clear to the inventors that fractional GNG, that is % of glucose production from GNG, was the key biomarker with regard to BES. While glucose Ra is somewhat useful (and using glucose Ra and fractional GNG, one can also determine GNG rate of production, since fractional GNG×glucose Ra=GNG rate of production), fractional GNG alone can be used to accurately assess the BES and nutritional needs of a patient.

While there are methods in the art that can be used to estimate fractional GNG and thus assess BES (3, 55-57) the current invention discloses new, improved, simplified means to estimate fractional GNG.

The current art views a sedentary or unconscious patient as resting, and thus not needing any nutritional support beyond that of a resting patient, because he or she is physically inactive. The current art also may view some critical illnesses as hypermetabolic, and in need of additional caloric support. Even in such cases, an accurate assessment of BES does not exist, and the nutritional support is often delayed and the nutritional management is based on formulas not necessarily specific to the patient's needs. Over time, the inventors realized that many patients, including comatose, ill or injured persons, are often in a catabolic (body tissue and energy storage breakdown) state because of the stresses of illness or injury. Based on various empirical observations, the inventors have seen such ill or injured patients with fractional GNGs well above 25%, which is similar to that of stressed, intensely exercising individuals or even starving ones.

In fact, by definition, GNG involves catabolism of body tissues to support production of glucose, since it is a less favored, inefficient method of glucose production. Glucose is an essential body nutrient and unique fuel for tissues such as brain, nerves, kidneys and red blood cells. To heal and gain strength an ill or injured person needs macronutrient nutrition, in particular, including glucose or glucose precursors.

Another embodiment uses an estimate of the absolute rate of GNG in mg/kg/min, in addition to the % GNG, as a biomarker. This requires an estimate of glucose Ra, in addition to fractional GNG, in order to yield and estimate of the absolute rate of GNG (absolute rate GNG=glucose Ra×fractional GNG). In the late 1970's and early 1980s, using radioactive tracers of glucose and lactate the inventors, among others (11, 23) saw that exercise and exercise training increased the ability of laboratory rats to maintain normal blood glucose concentration (also referred to as [glucose]) by increased capacity for making new glucose via GNG, using precursors such as lactate. In humans and other mammals, lactate production takes place in working muscles, among other tissues, whereas the conversion of lactate to glucose generally takes place mostly in the liver and kidneys. With the advent of stable, non-radioactive isotopes, the inventors, among others, studied men resting and exercising in a laboratory at sea level and developed technology to measure gluconeogenesis in resting and exercising men. Then, in the late 1980s, the inventors, among others, were able to use stable isotopes to measure and compare glucose and lactate fluxes in men resting and exercising in a laboratory at sea level and then under the added stress of the 14,000 feet elevation on Pike's Peak (9, 10). Among the many remarkable findings of such studies were enhanced ability of the subjects to both produce and use lactate for energy, in part by converting lactate to glucose via GNG and directly oxidizing the remaining lactate.

In addition, using stable isotopes of glucose and lactate, the inventors, among others, (21, 22, 39) made measurements showing enhanced GNG from lactate in smokers compared to non-smokers while exercising. Subsequently, over the course of decades of experimentation the inventors became experts in the science and technology of studying human physiology and of using isotope tracers to measure various metabolite flux rates in humans and other mammals engaged in exercise and other above-mentioned stresses.

For the inventors, lessons learned in the laboratory were complimented by a far wider set of experiences that involved the acquisition and transfer of knowledge that occurred within the context of general research in the field. Areas of experience included providing consulting and other services to business, scientific and governmental organizations. Additional areas of experience included serving on review boards and providing editorial duties for scientific journals.

The invention benefits treatment of an ill or injured person by using fractional GNG as the critical biomarker. While the general concept of estimation of fractional GNG by itself is not new, see, for example (3, 14, 20, 26, 27, 73, 74) the invention introduces new and improved systems and methods for such estimation. The invention also further uses these estimates as a highly useful determinant of the balance of BES, e.g., catabolism vs. anabolism and nutritional needs of an ill or injured patient in order to treat, feed and provide nutrition to the patient appropriately. For discussion of the general concept of the general use of biomarkers and measurement of various other aspects of metabolic flux see, for example (28, 65).

In addition to other improvements, the invention includes the improvement of continually or dynamically estimating fractional GNG, thus providing an ongoing basis by which to understand the BES of the patient and thus treat the patient, in addition to point measurement of fractional GNG. The invention includes a new metabolic diagnostic test to assess fractional GNG to determine the underlying metabolic and nutritional status, or BES, of a patient. The scientific literature increasingly suggests that such measurements should be made, neither specifies how to specifically interpret such information in the context of the metabolic and nutritive state of the patient, nor how to proceed on this information in terms of formulations and amounts of such formulations (75). In underfed patients, the liver, and to a lesser extent the kidneys, are the body organs that make new glucose from GNG. The invention also includes using the information derived from the test above to articulate information on the metabolic state and nutritive needs of a patient.

Estimating Fractional GNG

In a preferred embodiment, fractional GNG is estimated, which alone can be used as a highly useful, even determinative biomarker of BES. The basic principle is to label a portion of the patient's body water and then to estimate the portion of glucose production that becomes labeled via the GNG pathway. Because a label such as deuterium can be incorporated onto different positional carbons of glucose depending on whether the glucose was produced by GLY or GNG, such labeling can be used to estimate fractional GNG in the invention.

To function as an effective precursor label, the proportion of body water to be labeled must be large enough to give an accurate measurement of isotopic enrichment in both body water and blood glucose by whatever detection mechanism is used to determine the isotopic enrichments. It should also be highly sensitive so that relatively small blood samples can be taken for comfort and efficacy, and to reduce the cost of isotopic labeling and analyses. In a preferred embodiment, that label is deuterium, that is, the hydrogens in the water are the deuterium isotope (written as ²H or D) and D₂O is added to body water.

This deuterated water (generally commercially available at >98% purity) is generally introduced intravenously to the patient. In a preferred embodiment, an amount of deuterated water that approximates 0.3-0.5% of body water is given to the patient as a bolus. This amount is typically estimated by assuming 70% of body weight is water. Within a few hours, the labeled water both equilibrates with body water and is incorporated into blood glucose via the GLY and GNG pathways due to rapid isomerization between fructose-6-phosphate and glucose-6-phosphate during the process of glucose production. The hydrogen atoms on carbon 2 on glucose will be labeled via glucose production in proportion to the labeling of body water, and can be used to validate the % labeling of body water number enriched with deuterium.

By contrast, hydrogen atoms on carbons 1, 3, 4, 5, and 6 of glucose will be enriched with deuterium during transit of precursors through the GNG pathway. The hydrogen atoms on carbons 1, 3, 4, 5, and 6 of glucose will be labeled equally during GNG due to isomerization of glyceraldehyde-3-phosphate to dihydroxyacetone phosphate by triose phosphate isomerase and a series of equilibration reactions between phosphoenolpyruvate and dihydroxyacetone phosphate. The abundance of label at each of these carbons thus each represent GNG enrichment, though the average of these carbons (or an average of some) can be used for a potentially more accurate measurement. Thus, for example, the fraction of hydrogen atoms enriched by deuterium on C-1 of glucose will be equal to that on C-5, but each will have an amount smaller than the enrichment at C-2 due to the combined pathways of GNG and GLY.

In a preferred embodiment, a blood sample is taken after this initial bolus, and the glucose is extracted using standard methods known in the art via solvents. In a preferred embodiment, the glucose is converted to the penta-acetate molecule shown in FIG. 2, approximate MW 390, so that this glucose derivative can be detected in a gas chromatograph (“GC”) mass spectrometer (“MS”). The hydrogen-deuterium atoms on C-2 are removed during ionization so that we can isolate the carbons enriched by deuterium during GNG, thus obtaining the average GNG enrichment. This mass to charge (m/z) ion has a non-labeled molecular mass (“m”) of 169 and charge (“z”) of 1. If the ion is enriched with a deuterium at one of the carbons, then its m/z will be 170.

In one embodiment, the invention can be practiced without chromatography. Sugar measured without a chromatography step to isolate glucose from other blood sugars such as fructose and galactose would still be about 95% glucose, and so a meaningful number for glucose can be obtain without separation. Carbohydrate digestion produces a high percentage of glucose as the fundamental energy source for cell metabolism. Two other forms of sugars, galactose, and fructose, are also products of carbohydrate digestion. Despite the relatively high percentage of digested fructose and galactose (about 20%), after gastrointestinal absorption, the liver enzymes convert most of these sugars to glucose, resulting in the 95% number.

Of course, some of the ions will be enriched at more than one carbon, and by more than one isotope. For instance, endogenous (background) isotopic enrichment of carbon in body substances by (¹³C) approximates 1.09%. Similarly, the endogenous (background) deuterium enrichment is very small, approximately 0.015%, and the target D₂O enrichment in body water is approximately 0.3 to 0.5%, the background deuterium will not meaningfully affect estimation of fractional GNG as described here. It can in any case be corrected for, if desired.

The literature contains no reference for the method of determining fractional GNG and isotopic enrichment in body water following administration of D₂O that we describe here. However, others have used different methods using measurements of the isotopic enrichment of glucose following administration of D₂O and comparing to the enrichment in body water (20, 30, 45).

The ratio of 170/169 ions (further divided by 6, the number of hydrogen atoms on this ionized glucose fragment) divided by body water enrichment will thus yield an abundance value for fractional GNG. The body water enrichment value can either be taken from the bolus to body weight approximation described above (and, in a preferred embodiment, intended to be 0.3 to 0.5%), or estimated from the glucose carbon 2 enrichment via GLY as described in this equation: Fractional GNG=((abundance170/abundance 169)/6)/fraction of body water labeled

For reference, a standard chemical representation of glucose, approximate molecular weight (“MW”) 180, in shown in FIG. 1 (specifically the biologically dominant confirmation alpha-D-glucose). That same glucose molecule with each of the 7 hydrogens replaced with the marker deuterium (D) is shown in FIG. 2.

FIG. 2 is a standard chemical representation/illustration of the molecule glucose, with all seven hydrogens replaced with deuteriums (as labels).

FIG. 3 shows the penta-acetate glucose derivative, approximate MW 390, that is used in the GC/MS analysis method, in a preferred embodiment of the invention.

FIG. 4 shows a fragment of the penta-acetate glucose derivative, approximate MW 331, as well as the same molecule with different isotopes (MW 332, etc.)

FIG. 5 shows a fragment of the penta-acetate glucose derivative, approximate MW 271, as well as the same molecule with different isotopes (MW 272, etc.)

FIG. 6 shows another fragment of the penta-acetate glucose derivative, approximate MW 169, as well as the same molecule with different isotopes (MW 170, etc.)

In a preferred embodiment of the invention the body water enrichment is taken from observing the abundance of the labeled penta-acetate glucose derivative MW 331. This ion has a non-labeled molecular weight of 331 and charge of 1. Since this ion retains all carbons and hydrogens of the base glucose molecule, it is enriched by both GLY and GNG, at one of the seven hydrogens associated with the six carbons of the glucose, resulting in an ion with molecular weight of 332. Thus the abundance of this molecule represents enrichment by both pathways. Enrichment at carbon 2 is by both pathways, and enrichment at the other carbons is only by GNG.

FIG. 7 shows a schematic mass spectrum focusing on the 331 ion. As stated, relative abundance of the 332 ion (marked with one deuterium) vs. the 331 ion represents enrichment by both GLY and GNG pathways.

FIG. 8 shows a schematic mass spectrum focusing on the 271 ion. Since this ion has lost the hydrogen at carbon 2, it cannot be marked by the GLY pathway. The ratio of 272 to 271 thus represents the enrichment due only to GNG. Since the ion may also exist in a configuration where the hydrogen is still present in the molecule, the estimation of enrichment due to GNG may be modified by a correction factor, in one embodiment 1.0/0.9, because about 90% of the molecules exist in the configuration without the hydrogen at carbon 2.

FIG. 9 shows a schematic mass spectrum focusing on the 169 ion. Since this ion has lost the hydrogen at carbon 2, it cannot be marked by the GLY pathway. The ratio of 170 to 169 represents the enrichment due only to GNG. Since the ion may also exist in a configuration where the hydrogen is still present in the molecule, the estimation of enrichment due to GNG may be modified by a correction factor, in one embodiment 1.0/0.65, because about 65% of the molecules exist in the configuration without the hydrogen at carbon 2.

Since we have information on both pathways, we can establish a baseline for the amount of label produced by both the GLY and GNG pathways. The ratio of 332 to 331 represents enrichment by both pathways. When either the 170/169 or 272/271 ratios (or the average of both) is subtracted from this, this yields an estimate of the % of body water labeled, since body water is the starting point for both pathways of glucose genesis. This ratio can be used to confirm the % of body water labeled, in one embodiment. We can also have a % body water label baseline based on the amount of labeled water introduced into the body compared to body weight and/or total body water estimate (generally body water is assumed to be 70% of body weight) in another embodiment. If the ratio of 332/331 minus 170/169 or 272/271 or both differs from this, we can use the average or some other combination of these numbers to establish a baseline for % body water labeled, in another embodiment.

Note that in the above schematic mass spectra, the relative abundance of ions is represented by sharp, one-dimensional lines. The abundances are essentially represented on the y-axis as intensities. In reality, the intensity readings in mass spectra show up as two-dimensional peaks (hopefully, relatively sharp). The signal/intensity/abundance of each ion is generally calculated as the area under the curve of that peak. FIG. 10 shows an actual Selected Ion Monitoring (“SIM”) GC/MS spectrum of the current invention, showing peaks for selected ions 331 and 332. In any case, it should be noted that the units of the y-axis are not generally important, as long as the abundance is adequate for good chromatography, since what we care about are intensity/abundance ratios, and the ratios are dimensionless.

In a preferred embodiment, the GC/MS used is the Agilent GCMSD 5973. Of course, other types of GC/MS devices or other types of mass spectrometers such as liquid chromatographs can be used, provided that the enrichment is sufficient to be accurately detected and the molecules, or derivatives and fragments of the molecules representative of the relevant label or labels can be detected. Other types of mass spectrometers such as, but not limited to, three-dimensional quadrupole ion trap, linear quadrupole ion trap, orbitrap, sector, time-of-flight, Fourier transform ion cyclotron resonance or other detectors. Such detectors can be used alone or in combination (called tandem mass spectroscopy), e.g., triple quadrupole, quadrupole ion trap.

The creation of ions can occur by a variety of methods and systems, including, but not limited to, electron ionization (“EI”) and chemical ionization (“CI”) used for gases and vapors, electrospray ionization, nanospray ionization, matrix-assisted laser desorption ionization (“MALDI”), inductively coupled plasma (“ICP”), glow discharge, field desorption, fast atom bombardment (“FAB”), thermospray, desorption/ionization on silicon (“DIOS”), direct analysis in real time (“DART”), atmospheric pressure chemical ionization (“APCI”), secondary ion mass spectrometry (“SIMS”), spark ionization and thermal ionization (“TMS”). These ionization techniques result in the transformation of the molecule to an ion or multiple fragments of ions. Various chromatographic techniques, for example, gas chromatography (“GC”) and liquid chromatography (“LC”) can be combined with the mass spectrometer detectors. For LC/MS the interface between liquid phase and gas phase typically uses either nanospray ionization or electrospray ionization.

The invention can also be used with single “purpose-built” mass spectrometers. Distinguished from conventional central laboratory mass spectrometers, purpose-built mass spectrometers, typically are small, single biotechnology application, mass spectrometers that use miniaturized molecular traps operating near atmospheric pressure with small versions of pumps, ionizers, detectors and electronics needed. A handheld version can take a small blood sample so that tests such as % GNG can be easily and routinely sampled.

The invention can use deuterium oxide (D₂O) alone, or D₂O with either D₂-glucose, or [1-¹³C]glucose tracers administered intravenously upon admission to a hospital intensive care unit (“ICU”), in preoperative preparation or other forms of hospital admittance in order to establish baseline values for glucose Ra, % GNG, and absolute rate of GNG. In a preferred embodiment, assuming when blood glucose is in the normal range without exogenous intravenous glucose supplementation, the use of D₂O alone would be sufficient to yield % GNG as the sole biomarker, and analysis of % GNG alone is a preferred embodiment of the invention.

In short, estimation of % GNG consists of the intravenous administration of tracer or tracers, a small blood sample (small enough in fact for the diagnostic to be used in infants and children), preparation of sample for analysis and mass spectrometry to determine the mass isotopomer distribution of the incorporation of D₂O into the product glucose and the deuterium enrichment of the precursor body water. Our relatively easy, fast and cost effective invention can be easily deployed in hospitals and trauma centers throughout the world. In other preferred embodiments, we can combine % GNG estimates with other analyses (D₂O plus either D₂-glucose (2 deuteriums at C-6), or [1-¹³C]glucose (glucose with a carbon 13 at C-1), to yield estimates of glucose Ra and absolute rate of GNG. This would give additional information as to the to determine metabolic and nutritional state of the patient. Expanding on previous methods using mass spectrometry to estimate fractional GNG (20, 30, 44), we propose new stand-alone infusates and diagnostic methods. Using oral and vascular administration of D₂O (²H₂O) and a single, small blood sample, the fractional GNG estimate and deuterium enrichment in body water (D₂O or ²H₂O) (precursor) can be simultaneously measured using the ion fragmentation patterns resulting from a single mass spectrum. When the average deuterium (D or ²H) enrichment (over glucose carbons 1, 3, 4, 5, 6) is used to determine % GNG, we can call this the “averaging” fractional GNG method of estimation.

When divided by the enrichment of deuterium in body water (i.e., precursor), the fractional GNG estimate (glucose being the product of this pathway), yields the estimation of fractional glucose production from GNG, which we call fractional GNG or % GNG—the terms are used in this invention interchangeably. Instead of performing a separate analysis for the determination of the isotopic enrichment of deuterium in body water, we propose to use multiple fragments that result from the penta-acetate glucose derivative and mass spectrometry. Our invention for the averaging GNG estimate method is to measure the total deuterium enrichment of all hydrogens of glucose and subtracting the enrichment of deuterium on C-1, C-3, C-4, C-5 and C-6, the difference of which results in calculation of the enrichment of deuterium on C-2 of glucose. The enrichment of deuterium on C-2 is equivalent to the enrichment of deuterium in body water. Expressed in another way, enrichment of deuterium on C-2=(1,2,3,4,5,6,6-H₇−1,3,4,5,6,6-H6).

Therefore fractional GNG=average (1,3,4,5,6,6-H6)/(1,2,3,4,5,6,6-H7−1,3,4,5,6,6-H6).

The penta-acetate derivative of glucose contains all 6 carbons and 5 acetate functional groups that have replaced the native glucose hydroxyl groups. With methane chemical ionization (CI) and electron impact ionization (EI) the first prominent fragments are mass-to-charge (m/z) 331 and the related naturally occurring isotopomers (m/z 332, 333 and 334). This “331 fragment” contains all the carbons of glucose and all the hydrogens of the glucose molecule (i.e., C-1, C-2, C-3, C-4, C-5, C-6 and H-1, H-2, H-3, H-4, H-5, H-6, H-6 [also can be written as 1,2,3,4,5,6,6-H7] (7 hydrogens total)). The other ion fragments of interest in the proposed method are m/z 169 and its related naturally occurring isotopomers (m/z 170, 171, 172). Similar to the 331 fragment, the 169 fragment also contain all the carbons of glucose, but a different number of related hydrogens (i.e., C-1, C-2, C-3, C-4, C-5, C-6, and H-1, H-3, H-4, H-5, H-6, H-6 [or 1,3,4,5,6,6-H6]). Aspects of our invention are recognition of the loss of H-2 from the 169 fragment, and inclusion of H-2 in the 331 fragment of the penta-acetate derivative of glucose following the administration of D₂O and the process of GNG.

Due to complete hydrogen exchange with body water during the extensive glucose-6-phosphate

fructose-6-phosphate isomerization, the enrichment of ²H at C-2 of glucose represents body water enrichment. Using the difference of ion intensities between the two fragments identified above yields both the “average” enrichment of deuterium using ions 169 and 170 [(170/169)/6], plus the body water enrichment calculated from the difference between the M+1 ratio from ions 331 and 332 (332/331) and the M+1 ratio of ions 169 and 170 (170/169). Hence, fractional GNG can be estimated by comparing the deuterium enrichment on C-2 with the “average” enrichment of ²H on a glucose penta-acetate derivative following the administration of D₂O.

Alternatively stated, in one embodiment, fractional GNG can be calculated by dividing the “average” ²H glucose isotopic enrichment (the product) by the body water enrichment following administration of water and D₂O (the precursor), see, for example, (20, 30, 58). Restated another way, ²H enrichment on C-2 of a glucose penta-acetate derivative following administration of D₂O is due to both GNG and GLY. However, to reiterate, our new and novel method of measuring % GNG depends on determinations of the positional isomers of deuterium labeled glucose during GNG, an assumption that has been verified independently (20, 30). And any one or more of the GNG enriched carbons can be used to arrive at the % GNG estimate.

To review the formulas relevant to the invention:

M+1 ratio=m/z (M+1/M); M and M+1 represent ion fragments from mass spectrometry

The M+1 ratio can also be represented as (M+1/Sum (M+(M+1)). For example using ion fragment 331, M+1 ratio=332/(331+332).

Mole Percent Excess (“MPE”)=M+1 ratio_(sample)−M+1 ratio_(background); sample is blood sample acquired after administration of ²H₂O, and background is blood sample acquired upon admittance to hospital and before administration of D₂O. M+1 ratio (332/331)−M+1 ratio (170/169)=body ²H₂O

M+1 ratio (170/169)_(sample)−M+1 ratio (170/169)_(background)=Total MPE

Total MPE/6=average ²H enrichment of C-1, C-3, C-4, C-5, and C-6 blood glucose penta-acetate derivative

Fractional GNG=average ²H enrichment/body ²H₂O

In a preferred embodiment, the method of invention is comprised of three independent parts. Part 1 comprised of two sub-parts, (1A) administering D₂O to an ill or injured patient or to a healthy control in who GNG needs to be measured, and (1B) measure the glucose penta-acetate ion fragmentation patterns by mass spectrometry, as described above.

Sub-part 1A

At the start of treatment, e.g., on admission to a research laboratory, hospital or clinic for ill or injured patients, or research laboratory, for healthy subjects and scientific study, and before administration of D₂O, a background blood sample should be drawn and prepared for analysis. The background sample is useful because, depending on a patient's dietary and environmental history, small and variable amounts of ²H and ¹³C isotopomers naturally occur in body water, blood metabolites and other body compartments. After this background blood sampling and analysis, a constant infusion of deuterium oxide will commence (with or without a bolus depending on the whether % GNG needs to be assessed in the first several hours of admission). Because the deuterium oxide equilibrates with the body water, a desired enrichment can be achieved and maintained throughout the entire hospitalization period.

The desired isotopic enrichment of body water (in one embodiment about 0.3-0.5%, or adequate for ion intensity comparisons from the utilized method of mass spectrometry) will be adjusted by the constant infusion of D₂O and verified by the determination of deuterium enrichment on C-2 (as described above using the difference in ion intensities between ion fragments 331 and 169). Alternatively the determination of body water enrichment can be determined by isotope ratio mass spectrometry (31, 66) or using an isotopic exchange with acetone method (81). Then, when needed and as frequently as necessary, a small blood sample can be drawn to determine fractional GNG on an ongoing/dynamic basis. As nutritional support is augmented using the following parts of the invention, the fractional GNG will be controlled, such as within the target range (20-25%) in a preferred embodiment, varied to mimic a normal daily circadian pattern, or varied to yield any particular % GNG ranging from 0 to 100% in other embodiments.

The frequency of blood sampling following D₂O administration, the subsequent calculation of % GNG, and adjustment of enteral and parenteral nutrition is limited by the time needed for analysis. Given current technology, a 2-hr frequency should be practical. However, as technology advances, the frequency of sampling may increase. In a busy hospital setting, morning, noon and evening sampling may be necessary to estimate % GNG and other biomarkers.

Sub-part 1B

The analysis of the data derived from the analytical process in Part 1 determined from the mass isotopomer distribution of deuterium incorporation into glucose yields the rate of GNG, which can also be understood as the % of Ra glucose derived from GNG precursors (mainly lactate). This is referred to as fractional GNG or % GNG. Fractional GNG is proportional to the rate of glucose production. In a normal resting person, % of total glucose production to support the brain approximates 25%, a very high percentage considering the mass of the brain in comparison to the rest of the body. Blood glucose demands increase in injured persons regardless of the site of injury, and the balance of glucose Ra from GLY and GNG varies depending on nutritional state, time and metabolic needs of various body tissues. Paradoxically, following brain injury, cerebral glucose uptake is stunned and diminished, however, the % of cerebral glucose uptake from GNG rises, as has been observed by the inventors and other researchers, in studies to be published in the coming months.

In healthy, uninjured persons the % GNG can fluctuate between ˜10% (over fed), to ˜20-25% (appropriately nourished) to as high as ˜90% (in undernourished and catabolic patients). Our observations show that % GNG approximates 70% for TBI persons in the ICU, as has been observed by the inventors and other researchers, in studies to be published in the coming months.

Importantly, even though the % GNG will follow a circadian fluctuation in a traumatized or critically ill patient; this fluctuation can be minimized by the provision of nutritive support to achieve a normal (20-25) % GNG, indicative of normal metabolic and nutritive states. By this means, “exquisite” glycemic control and Ra glucose, without the use of conventional or intensive insulin therapy, can be achieved, which may be of critical benefit to the patient.

In describing % GNG it needs to be understood that % GNG is a variable that can have physiological range of 0 to 100%. Based on our work as well as that of others, the stated target range of 20-25% in healthy post-absorptive individuals, is a biomarker for adequate nutrient delivery in an ill or injured patient or other individual incapable of taking adequate macronutrient nutrition, as defined by the Harris-Benedict (32) or Institute of Medicine equations (8, 51). In a preferred embodiment of the invention, nutrition is provided so that % GNG is between about 15 and 30%. In another preferred embodiment of the invention % GNG of about 20-25% is aimed for based on studies on healthy young individuals 3-4 hours after having eaten (3, 24, 26, 27, 58, 73).

Part 2

Part 2 articulates the metabolic and nutritive state, also known as body energy state (76) of the patient. For Part 2 the acquisition of the mass isotopomer distribution of the deuterium and hydrogen content in the body water and the glucose, taking into consideration the natural occurrence of isotopes of carbon and other atoms with naturally occurring isotopes, consists of selective ion monitoring (“SIM”) of the mass to charge ratio (m/z) of the ions of interests coupled with an integration of the SIM to deduce the response factor associated with the abundance of the ions of interests as they relate to the precursor and product relationship.

The invention also includes a method and system to compare the precursor and product relationship based on the patient's baseline measurement and the daily (or multiple daily) measurements taken from the patient. The invention, in a preferred embodiment, has a database that informs the basis from which the nutritional status was evaluated and the prescription of nutritional support was determined. With the additional process of part 1, the database will contain variables for the relevant ions (e.g., 331, 332, 272, 271, 169, 170) to calculate fractional GNG and body water enrichment as it relates to infusion of the tracer deuterium oxide and the precise, prescription nutritional support. As well, the system will contain non-identifiable data on patients, the severity of injury on entry into the study, the initial % GNG, the enteral and parenteral nutrition provided, and patient outcomes.

It will be appreciated that many of the described methods can be intermediated and implemented automatically by a computer, or special-purpose hardware, or some combination of both, as such systems are well known in the art. Specialized software or hardware of the invention could read the intensity of signals provide my mass spectra and automatically calculate the ratios and other important data to give a reading of fractional GNG. Such readings could automatically be stored in databases or computer memory and presented to users in various visual forms. The software could also make recommendations as to feeding protocols and times, frequency of patient sampling, or simply carry out these methods automatically.

The invention as such can be implemented on any suitable computer system. A typical, general purpose computer system suitable for implementing the present invention includes any number of processors that are coupled to memory devices including primary storage devices such as a read only memory, random access memory and hard drives. Any one of many data and database architectures can be used to store and retrieve methods, protocols and recommendation, to store data, and to communicate with server side assistance through the Internet and other networks.

A hardware system may be specially constructed for the required purposes, or it may be a general-purpose computer, such as a server computer or a mainframe computer, selectively activated or configured by a computer program stored in the computer. The processes presented above are not inherently related to any particular computer or other computing apparatus. In particular, various general-purpose computers may be used with programs written in accordance with the teachings herein, or, alternatively, it may be more convenient to construct a more specialized computer system to perform the required operations.

Such a general-purpose computer system suitable for carrying out the processing in accordance with one embodiment of the present invention can be a server computer, a client computer, or a mainframe computer. Other computer system architectures and configurations can be used, made up of various subsystems described below, includes one or more microprocessors (or central processing units). Using instructions retrieved from memory, the microprocessor controls the reception and manipulation of input data, and the output and display of data on output devices.

Part 3

Part 3 relates to nutritive methods, formulations and amounts. With the prescription of medicine determined following parts 1 and 2 dictated by the invention for each patient, the attending physician shall administer the level of nutritive support to administer to each patient to normalize the % GNG. Further, the attending physician or other health care professional shall utilize information from continual determinations of GNG and nutrient delivery following application of parts 1 and 2 of the invention for each patient as they recover or as conditions change. The invention will prescribe feeding protocols for the patient, as follows, based on general nutritional concepts described in (8, 51).

(A) A preferred form of treatment will consist of the intravenous infusion of the gluconeogenic precursor, including any of the following in combination or alone: L-(+)-lactate salts, other lactate compounds, L-(+)-pyruvate salts, other pyruvate compounds, L-(+)-lactate alone, lactate plus other amendments included in lactate, pyruvate and similar nutritional molecules are herein referred to as monocarboxylate compounds (“MCC”). The metabolic precursors of glucose in the GNG pathway are herein called GNG precursors. These include many MCCs, such as those listed herein, as well as other compounds, such as some amino acids (e.g., alanine) and glycerol compounds.

These nutritive formulations are referred herein as cocktails, infusions, formulations, MCC cocktails and GNG precursor cocktails. To provide nutritive support and reverse body catabolism to anabolism following trauma or chronic illness, the rate of MCC infusion would range from high (13) to low (13) as governed by the individually measured % GNG and glucose appearance rates: High(Maximum)MCC Cocktail infusion rate(mg/min)=glucose Ra (mg/min)  A1: Low(Minimum)MCC Cocktail infusion rate(mg/min)=glucose Ra (mg/min)×(% GNG)=absolute rate of GNG  A2:

In its simplest form, the MCC cocktail would be sodium-L-(+)-Lactate prepared by titrating L-(+)-Lactic acid with NaOH (24, 52, 55-57). Briefly, the MCC infusion cocktail is prepared by mixing 30% L-(+)-lactic acid solution (e.g., Sigma) in 2 N NaOH to pH 4.8. The invention, in one embodiment, specifies an initial infusion rate would deliver 11-50 (micro Moles per kg of body weight per minute) μMoles/kg/min, with maintenance infusion rate targeting blood lactate concentration of 3.5-4.5 mM. Higher blood lactate levels (6 mM) have been seen without ill effects (57, 71). Consistent with section methods described above, assuming a formula weight of 112 mg/mMol for sodium lactate, an infusion rate of 11 μMoles/kg/min would deliver the mass equivalent of 1.0 mg/kg/min of glucose, an infusion rate of 23 μMoles/kg/min of sodium lactate MCC would deliver the mass equivalent of 3 mg/kg/min glucose, whereas an infusion rate of 50 μMoles/kg/min would deliver the mass equivalent of 4.5 mg/kg/min of glucose. Ideally, the MCC is prepared from highest purity materials, is pathogen free, certified for human pharmaceutical use and is delivered into a large central vein, but peripheral vein can be used if administered with physiological saline to minimize osmolality and pH effects at the infusion site that might provoke phlebitis of hemolysis.

In one embodiment, the starting MCC infusion rate is approximately 3 mg/kg/min, or in an alternate embodiment, 100% of glucose Ra, as has been observed by the inventors and other researchers, in studies to be published in the coming months. In one embodiment, this can be done even without estimating % GNG, Ra glucose or other biomarkers. This route and amount of vascular lactate administration has been shown to be safe (55-57, 71). The amount also corresponds to the average empirically determined Ra glucose in TBI patients (74), as has been observed by the inventors and other researchers, in studies to be published in the coming months.

The invention provides for adjusting the nutrition, including MCC infusion rates, such that a target % GNG is achieved. To some, results of studies of the extent of gluconeogenesis in humans might seem quite variable; however, if results are viewed from the context of subject time since last eating, then a clear pattern emerges: GNG is suppressed as nutrients enter the gut, portal and circulation (e.g., 0-15% of glucose Ra), and 20-25% of glucose Ra 3-4 hr after a mixed, CHO (carbohydrate) containing meal, and the percentages rises continuously thereafter (74).

(B) An alternative and also preferred form of treatment will involve Procedure A plus either (B1) enteral nutrition via nasal gastric or nasal jejunal tube, or parenteral nutrition (B2) via intravenous catheter. If these, Method B1 is useful because nutrients will enter the stomach and reach intestines, portal circulation and liver, thereby eliciting physiologically appropriate and anabolic local intestinal and long neural endocrine reflexes as well as general endocrine responses with signals reaching the liver, pancreas, muscles, heart, adipose, and brain including hypothalamus regarding the presence of appropriate nutritive energy support (79).

(B1a) The clinician shall proceed as in (A), above, but, as well, provide enteral nutritive support according to various protocols, such as the Appropriate Macronutrient Distribution Ranges (“AMDR”) as defined by the Institute of Medicine (“IOM”). These AMDR ranges are: carbohydrate in the range of 45-65%, protein in the range of 10-35% and fat in the range of 20-35%, with total daily energy input as determined by the TOM equations for men and women (8, 51) assuming no physical activity, but a 10% increase in total daily energy expenditure (“TEE”) to support hyper-metabolism of trauma and cover energy needs for tissue repair such that physical activity level (“PAL”) (8, 51)=1.1: Men: TEE=1864−9.72×age[yr]+PAL×(14.2×weight[kg]+503×height[m]) Women: TEE=1387−7.31×age[yr]+PAL×(10.9×weight[kg]+660.7×height [m])

(B1b) The clinician shall proceed as in (A), but as well provide enteral nutritive support from various protocols, such as according to the Appropriate Macronutrient Distribution Range (“AMDR”s) as defined by the Institute of Medicine (51), and that energy is delivered according to the Harris-Benedict Equations (32): Men: TEE=66.473+13.7516 W[kg]+5.0033H [cm]−6.7550Age [yr] Women: TEE=655.0955+9.5634W[kg]+1.8496H[cm]−4.6756 Age[yr].

(B2) The clinician shall proceed as in (B), but nutrients will be administered into the blood via an indwelling catheter. Monitoring and adjustment of MCC and macronutrient infusion rates will be similar to (A) and (B1).

(C) Another embodiment of the invention relies on robust, scientifically determined underpinnings of the metabolic and GNG responses to trauma, including neurotrauma, as has been observed by the inventors and other researchers, in studies to be published in the coming months, and is to be regarded as an emergency procedure when isotopes and analytical equipment are unavailable and the patient needs to be sustained until relocation to an appropriately equipped facility.

(C1a) The clinician shall commence intravascular infusion of Na⁺-L-(+)-Lactate at the rate of 3 mg/kg/min plus enteral nutritive support according to the AMDRs and TEE estimates as given by the Institute of Medicine (“IOM”) (8, 51).

(C1b) The clinician shall commence intravascular infusion of Na⁺-L-(+)-Lactate at the rate of 3 mg/kg/min plus enteral nutritive support according to the AMDRs and TEE estimates as given by Harris and Benedict (32).

(C1c) The clinician shall commence intravascular infusion of Na⁺-L-(+)-Lactate at the rate of 3 mg/kg/min plus parenteral (intravascular) nutritive support according to the AMDRs and TEE estimates as given by the TOM (8, 51).

(C1d) The clinician shall commence intravascular infusion of Na⁺-L-(+)-Lactate at the rate of 3 mg/kg/min plus parenteral (intravascular) nutritive support according to the AMDRs and TEE estimates as given by the Harris-Benedict equations (32).

(D) Another embodiment of the invention also relies on robust, scientifically determined underpinnings of the metabolic and GNG responses to trauma and is to be regarded as an emergency procedure when isotopes, analytical equipment and MCCs are unavailable and the patient needs to be sustained until relocation to an appropriately equipped facility. Such locations could include, for example, a battlefield or a rural setting.

(D1a) In a facility unequipped to determine % GNG the clinician shall commence intravascular infusion of D-Glucose at the rate of 1-2 mg/kg/min and enteral nutritive support according to the AMDRs and TEE estimates as given by the IOM (8, 51). The inventors have seen a rate of 3 mg/kg/min in TBI patients, as has been observed by the inventors and other researchers, in studies to be published in the coming months. However, experience teaches that it is difficult to maintain the desirable [glucose] in severely injured patients (78). In severely injured patients giving exogenous glucose (usually in the form of dextrose) may induce hyperglycemia thereby eliciting an insulin response or the need to administer insulin due to undesirably high [glucose].

This undesirable process can be described as a pattern of clinicians to clumsily trying to ride a “metabolic roller coaster” of intravenous dextrose followed by insulin and yet again dextrose, and the current invention can eliminate this problem. Importantly, while spending time, effort, resources and attention by managing [glucose] in patients by alternately adjusting infusion rates of dextrose and insulin, the clinician obtains little useful information or meeting patient nutrient needs. The current invention will enable clinicians to meet patient nutrient needs and serves to save clinician time and effort and releases clinicians from the responsibilities associated with managing the aforementioned metabolic roller coaster.

(D1b) The clinician shall commence intravascular infusion of D-Glucose at the rate of 1-2 mg/kg/min and enteral nutritive support according to the AMDRs and TEE estimates as given by Harris and Benedict (32).

(D1c) The clinician shall commence intravascular infusion of D-Glucose at the rate of 1-2 mg/kg/min and parenteral (intravascular) nutritive support according to the AMDRs and TEE estimates as given by the IOM (8, 51).

(D1d) The clinician shall commence intravascular infusion of D-Glucose at the rate of 3 mg/kg/min and parenteral (intravascular) nutritive support according to the AMDRs and TEE estimates as given by the Harris-Benedict equations (32).

(D1e) If enteral or parenteral support is unavailable, the clinician shall commence intravascular infusion of D-Glucose at the rate of 3 mg/kg/min which is the empirically derived best estimate of body glucose flux following a TBI or other injury, illness or situation, as has been observed by the inventors and other researchers, in studies to be published in the coming months. This elevated value of glucose flux that occurs after TBI or other injury, illness or situation, is indicative of a “hypermetabolic” state would be in contrast to the depression in glucose flux as might occur in a “hypometabolic” state, such as advanced ageing (see below, vide infra).

In a preferred embodiment, nutritive support treatment targets are % GNG 20-25%. In another preferred embodiment plasma [glucose] is targeted as 5-7 mM. In another preferred embodiment, plasma [lactate] is targeted as 3-4 mM. These targets can be achieved by adjusting MCC, enteral and parenteral administration rates either singularly, or in combination. However in methods C and D, % GNG will not be known. In these cases, in addition to adjusting MCC, enteral and parenteral administration rates, insulin therapy may be indicated above a certain [glucose] such as 7.8, or below 5.6 mM (75).

The robust nature of the GNG response to the stresses of injury can be supported by provision of an MCC, that can be comprised of one, or combinations of the following: sodium L-(+)-lactate, arginyl lactate, glycerol, glycerol tri-lactate, sodium L-(+)-pyruvate, arginyl pyruvate, glycerol tri-pyruvate, glycerol tri-acetate, β-OH-butyrate or acetoacetate [in which all monocarboxylate enantiomers are L-(+)-enantiomers], or mixtures thereof in which the relative amount of any single constituent could range from 0-100%. As well, embodiments of a MCC cocktail could include Ca⁺⁺, Mg⁺⁺, and K⁺-salts of lactate, pyruvate, alanine, β-OH-butyrate, acetoacetate, etc., as all are salts of monocarboxylic acids. However, sodium ion (Na⁺) is the main cation in plasma, normally 145 mM, other cations are far less abundant in plasma. For instance, normal values for K⁺, Ca⁺⁺, and Mg⁺⁺ are, respectively, 4, 2.5 and 1.5 mM. Hence, a mixture of inorganic lactate salts comprised of Na⁺, K⁺, Ca⁺⁺, and Mg⁺⁺ would be given in the ratio of 145, 4, 2.5, and 1.5. In this embodiment of invention, the main anion would be lactate, but phosphates (PO₄ ³⁻), hydrogen phosphate (HPO₄ ²⁻) and dihydrogen phosphate (H₂PO⁴⁻), in the amount of 1.0 mEq would be provided as well. Because Na⁺, K⁺, Ca⁺⁺, Mg⁺⁺, and H₂PO⁴⁻ are present in the plasma of healthy individuals at levels of 145, 4, 2.5, 1.5, and 1.0 milliequivalent per liter (mEq/1, this particular embodiment of MCC could be termed “Sanguisal” from the Latin words for blood (sanguis) and salt (53). The provision of sodium and other cations as a means to deliver lactate anions in an MCC has the advantage of reducing brain swelling following TBI, as has been observed by the inventors and other researchers, in studies to be published in the coming months and (15) as well as providing nutritive support to intensive care patients following trauma (70).

As an alternative to Sanguisal-L that uses lactate as the major anion (vide supra), Sanguisal-P will involve the use of pyruvate (P) as the major anion, while at the same time maintaining the above-stated levels of cations {Na⁺, K⁺, Ca⁺⁺, Mg⁺⁺, and H₂PO₄ ⁻ as are present in the plasma of healthy individuals: 145, 4, 2.5, 1.5, and 1.0 mEq/1}. Like it's counterpart lactate, pyruvate is the precursor to lactate in glycolysis. Further, pyruvate is an oxidizable fuel and GNG precursor whose metabolism may affect cell redox status if converted to lactate. Although typically present in 1/10 or lesser concentration compared to lactate, pyruvate has been introduced into the systemic circulation of large mammals in which the circulation has been interrupted to mimic cardiac arrest (61-63, 68). In such cases 100% pyruvate infusion raises the circulating pyruvate level, but more so, the circulating lactate level achieving a circulating L/P of 2-3 (69). None the less, because of its chemical structure, pyruvate has the advantage over lactate of serving as an antioxidant in the myocardium subjected to reperfusion injury, and, by extension exogenous pyruvate my also serve to scavenge free radicals in the brain after blood flow is interrupted.

A problem with regard to the use of Sanguisal-P, in contrast to the -L form, is that in circulation pyruvate is rapidly converted to lactate due to the effects of lactate dehydrogenase in red blood cells and the lung parenchyma (41). Hence, for the antioxidant properties of pyruvate (48), the optimal site of Sanguisal-P infusion would be in the carotid artery or ascending aorta. Still, by the ability to infuse mixtures of Sanguisal-L and Sanguisal-P into the systemic circulation, ascending or carotid artery, the clinician would have the opportunity to affect redox status in an injured brain. However, because carotid or ascending catheterization is uncommon even in the ICU, systemic solutions of a very low L/P ratio (i.e., high P/L) such as infusion of 100% Sanguisal-P, or a mixture of Sanguisal-P/Sanguisal-L of 2.0 (L/P=½ in the infusate), would serve to raise the arterial level of pyruvate relative to that of lactate.

It should be noted that one issue with aqueous pyruvate-containing solutions is the spontaneous degradation of pyruvate and the accumulation of unintended and possibly toxic substances in aqueous conditions. Accordingly, the manufacturing and storing Sanguisal P and Sanguisal L-P mixtures needs to be anhydrous. Water (pure and sterile) can then be added to he formulation immediately before delivery to the patient.

In using Sanguisal-L, Sanguisal-P, or other sodium salts of lactate or pyruvate the assumption is that the patient to be supported has normal renal function and is capable of managing the sodium load. In the event that the patient does suffer renal failure, then the use of Sanguisal or other sodium-based salts will need to be reduced to the levels where normal sodium, potassium and other plasma cations are in the normal range. In this case also, substrate availability in patients can be maintained by combinations of intravenous Dextrose (a synonym for glucose), with and without insulin, and enteral nutrition as described in section D, above. Still, however, % GNG will serve as the biomarker around which to provide enteral and parenteral nutrition.

Alternative Methods to Estimate % GNG

The invention is comprised of a three-part process to assess the metabolic status and deliver macronutrient energy to an ill or injured human or other mammal. The first part is to estimate the % GNG, the favored method is to utilize deuterium oxide (D₂O) alone, or D₂O with either D2-glucose, or [1-¹³C]glucose tracers administered intravenously upon admission to a hospital ICU (20).

One advantage of the new method is that the tracer needs to be given once that will suffice for measurements of GNG to be made daily for several days and a constant infusion can be started to offset the dilution of the enrichment of the deuterium oxide caused by intake of fluids. However, we have used primed-continuous infusions to measure glucose recycling or lactate incorporation lactate into glucose. The former method (glucose recycling) requires using D2-glucose (that does not involve carbon recycling, and a ¹³C-glucose tracer (e.g., [1-¹³C]glucose) in which the carbon recycles (26, 27). In this carbon-recycling method, % GNG=(100) Ra Glucose (from ¹³C-glucose) −Ra Glucose (from D2-glucose)/Ra Glucose (from D2-Glucose). Disadvantages of this method are that tracers will need to be given continuously over days, perhaps leading to weeks, and that assumptions need to be made over the extent of carbon isotope dilution in the Krebs (tricarboxylic acid) Cycle (37, 38).

Another method also uses deuterium oxide and measures the deuterium incorporation on glucose carbons using the mass isotopomer analysis technique with the aldonitrile penta-acetate and methyloxime-trimethylsilyl derivatives (42).

Another alternative method also uses deuterium oxide but measures the enrichment at carbon 2, 5, and 6 of glucose using the HMT (hexamethylebetetramine) derivative. Disadvantages of this method are the complexity in preparing the derivative (44, 45).

Another alternative method involves primed-continuous infusion of D2-glucose (and a ¹³C-lactate tracer (e.g., [1-¹³C]lactate) (3) in which the carbon from lactate recycles to glucose. Disadvantages of this method are that tracers will need to be given continuously over days, perhaps leading to weeks, and that assumptions need to be made over the extent of carbon isotope dilution in the TCA Cycle.

Another alternative method involves the primed-continuous infusion of H¹³CO₃ ⁻ (i.e., ¹³C-bicarbonate) that will be fixed as the result of isotopic equilibration during the process of gluconeogenesis (37, 65). Disadvantages of this method are the tracer needs to be given continuously over days, perhaps leading to weeks. Again, the method relies on assumptions on the extent of carbon exchange during GNG, with the extent of isotopic dilution subject to metabolic state of the individual (38).

Another alternative method involves the use of mass isotopomer distribution analysis (MIDA) using a labeled glycerol precursor. Disadvantages of this method include the large amount of tracer needed to make the measurement. (35, 58).

Another alternative method involves the use of [U-¹³C]glucose (72). This method was enhanced to the “Reciprocal pool model” by (34). Disadvantages of these methods are that the tracers need to be given over days and potentially weeks.

Still other methods for assessing GNG in vivo do not involve isotopomer detection via mass spectrometry, but instead rely on nuclear resonance spectrometry (MRS, or NMR), e.g., (46). The literature on isotopomer detection via MRS is less extensive, but the method may prove to be more sensitive, for instance extending the time between frequency of dosing with D₂O to estimate GNG, or % GNG. However, the large amount of deuterium oxide needed for the measurement may lack efficacy.

In a preferred embodiment to measure fractional GNG, D₂O, also called deuterium oxide or heavy water, either alone or in combination with [6,6⁻²H]glucose (i.e., DD-glucose or D2-glucose) or [1-¹³C]glucose) (20), is administered intravenously. Then, after a set amount of time a blood sample can be obtained, and the mass isotopomer distribution in the blood sugar glucose produced from the heavy water precursor can be analyzed to determine the percentage contribution of gluconeogenesis (% GNG) to the total rate of hepatic plus renal glucose production, alternatively termed glucose appearance (Ra glucose) that can be determined from the isotopic enrichment (“IE”) of D2-glucose in blood. Beyond the isotope tracer method noted by example for measurement of % GNG, other methods also exist to determine % GNG, see below (3, 26).

The major GNG precursor is the monocarboxylate, 2-hydroxy-propionate (also known as lactate) (3, 40, 54), which is also a major energy substrate for most body tissues (5-7), including the brain (28, 33, 64). As well, to lesser extents, the salts of other monocarboxylic acids are also gluconeogenic precursors; these include: pyruvate, acetate, acetoacetate, β-hydroxybutyrate, and related compounds, see below. Because at physiological blood pH (about 7.4) monocarboxylic acids (lactic, pyruvic, acetic, β-hydroxybutyric, acetoacetic acids, etc.) will be dissociated to protons and respective anions, here we refer the monocarboxylate anions lactate, pyruvate, acetate, acetoacetate, and β-hydroxybutyrate.

According to the invention, in one embodiment, the fractional GNG is used to determine nutritive support rate to achieve preferred glucose Ra and fractional GNG. For example, an injured patient may have an increased metabolic rate (hypermetabolic) and thus need both glucose and GNG precursor support. By contrast, an aging or chronically ill patient may have a depressed whole body metabolic rate (hypometabolic), but still an elevated need for GNG precursors without glucose support. Even with knowledge of [glucose], which is commonly measured, but without a clear picture of the fractional GNG rate (our biomarker for the metabolic and nutritive state of the patient), a clinician may not recognize that the patient is in a catabolic state and is degrading essential body stores to provide the precursors and energy for GNG.

Conversely, a clinician might induce a nutritional state that renders the patient overfed by administering too much nutrition because a lack of knowledge of the underlying metabolic and nutritional status of the individual patient. An overfed patient can result in significant metabolic stress and may result in complications including prolonged mechanical ventilation, infection risk, delayed hospital discharge and even increased morbidity (29, 47). Indeed, without knowledge of the fractional GNG and based on false assumptions of previous art, a clinician may be unaware of the body's attempt to supply glucose from gluconeogenesis, and, in fact, the clinician may inadvertently act to suppress GNG (78).

Application of the Invention to Various Injuries and Illnesses

By way of describing importance of our method for providing nutritive support to injured patients is to describe the condition of TBI (also known as intracranial injury). Such injuries occur when an external force suddenly impacts, and causes injuries to the brain (15). Often the mechanism of injury produces two, or more lesions, one a laceration or contusion at the site of impact or cranial penetration, and the other a contralateral contusion injury if the force of impact is sufficient to accelerate the brain such that it forcibly contacts the cranium at a vector directed by the initial impact. TBI can be classified based on severity, mechanism (closed or penetrating head injury), or other features, e.g., occurring in a specific location or over a widespread area (15, 28). Head injury usually refers to TBI, but is a broader category because it can involve damage to structures other than the brain, such as the scalp and skull (15). TBI is a major cause of death and disability worldwide, especially in children and young adults and the elderly. Causes include falls, vehicle accidents, and violence.

Typically, following severe TBI, patients are unconscious in a coma, are on life support in a hospital intensive care unit (“ICU”), and have less than 100% chance of surviving and less than 100% chance of regaining pre-injury cerebral functions if they do survive (28). More and more, sports related concussions in American football and other activities, involving loss of consciousness, or other neurological symptoms such as dizziness, nausea, the patient “seeing stars” and behavioral changes are becoming recognized as mild forms of TBI. Especially of concern is growing recognition of the frequency and severity of sports-related concussions to student athletes, still undergoing neural development, and who are particularly sensitive to repeated cerebral injuries. And finally, another source of TBI occurs to soldiers concussed, and injured in the field as the result of improvised, and other explosive devices.

Given this unfortunate background of TBI following vehicle accidents, falls, violence, sports and warfare, our method of determining the rate of GNG following trauma and restoring the rate to normative levels is becoming increasingly important because of the frequency and severities of injuries.

The description includes examples of patient treatment following trauma and chronic illness. The invention includes, methods for managing those extreme and other cases and instances when assessment of BES, diagnosis and treatment are appropriate. Such examples include, but are not limited to assessing BES of patients or others before and after surgery, before and after drug treatment or dietary intervention, or any situation in which knowing, or standardizing BES is essential for determining outcome of any treatment, or establishing the effect of said treatment on humans or other mammals.

GNG is part of normal physiology that includes the “fight-and-flight” response to emergency situations that is well-known in the art, see for example the classic work of Selye (67), and the reference books by Cannon, W. B. “The Wisdom of the Body” (17) and Brooks (12)). In both healthy and uninjured persons, gluconeogenesis works to maintain blood glucose concentration, or glycemia, in the normal range in the early morning hours after the previous evening's meal has been digested and nutrients cleared from the blood, and when the maintenance of glycemia depends on GNG (54). Commonly stated examples given to illustrate importance of the fight and flight response are evolutionary in nature, such as the need to flee predators, or catch large game animals.

While interesting, such examples are remote from contemporary human experience, but injuries and illnesses persist in society and are associated with comorbidities, including nutrient deprivation. Seen in the context of contemporary fight and flight responses, following TBI and other forms of trauma of the critically ill or injured patient the need to provide blood glucose is paramount because glucose is an essential fuel for the brain, as has been observed by the inventors and other researchers, in studies to be published in the coming months, and other tissues such as nerves, red blood cells and the kidneys (8, 51). Indeed, the dietary reference intake (“DRI”) for total daily carbohydrate (“CHO”) consumption was established based on the glucose needs for the brain (8, 51). Therefore, not only is the total body needs for glucose increased following TBI, but also elevated is the rate of gluconeogenesis from lactate and other GNG precursors, as has been observed by the inventors and other researchers, in studies to be published in the coming months.

The body's need for GNG is increased following TBI, and mimics the starvation state in which body tissues are cannibalized (catabolized or degraded), as is well-known in the art, for example see the textbook by Brooks (12). This pathway supplies byproducts of carbohydrate (e.g., lactate and pyruvate), amino acids (e.g., alanine), and fats (e.g., glycerol and ketones such as β-hydroxy butyrate and acetoacetate) (16). Of these, lactate is by far the most important GNG precursor, easily seen during exercise when blood lactate concentration is elevated (3-5, 7). Crucially, even though GNG provides a short term, fight- and -flight response to the emergency need for a glucose supply to the brain, nerves and other glucose requiring tissues, the price of GNG is to sacrifice (catabolize) essential body substances and tissues. Crucial also is the realization that the basic needs for glucose and other macronutrients by glucose-requiring tissues continue unabated whether those tissues are traumatized, or not. Hence, key underlying concepts of our invention are that glucose and other macronutrients are required, always, that the requirement is the same as normal or increased after trauma, and that the rate of GNG is a critical marker of body tissue catabolism following injury, and alone can be used to direct nutritional treatment.

Derived from such knowledge gained through innovative technology are clinical procedures and materials to support glucose Ra while minimizing % GNG, because GNG is the best real-time measure of body wasting. As well, we assert that these methods have application beyond TBI to the treatment of trauma and chronic and infectious illnesses, in general, because the same methods support the body corpus overall that is comprised of injured and non-injured tissues all requiring nutrient supply.

For a traumatized patient, cachexia, or body-wasting syndrome, is a problem because basal metabolic rate is elevated, but the person is unable to eat. Body weight loss, muscle atrophy and weakness and fatigue result leaving a person diminished even if they survive. In addition to trauma, other conditions and illnesses of life are accompanied by loss of appetite and cachexia. These include aging, infectious diseases (e.g., tuberculosis and AIDS), chronic diseases (chronic obstructive lung disease, multiple sclerosis and congestive hear failure), cancer and some autoimmune disorders. Regrettably also, exposure to environmental toxins (e.g., mercury) can result in cachexia, and occasionally there are some who are unable to access food and are starved. All such sick individuals and chronically ill patients who are unable to ingest adequate macronutrients to maintain body requirements, let alone restore health would also benefit from treatment by the invention we describe.

It has long been recognized that patient care in the ICU necessitates the monitoring of blood glucose concentrations due to the stress from critical illness. Some have identified insulin resistance and unsuppressed gluconeogenesis (i.e., when negative feedback from rising blood [glucose] fails to down regulate GNG) that results in the required monitoring of blood glucose in over 90% of ICU patients (83). Additionally, various attempts to control blood glucose concentration including hyperglycemia with blood glucose concentration of 180-215 mg/dL is considered beneficial.

Conversely, others have attempted to regulate blood glucose concentration to values between 80 and 110 mg/dL in an attempt to maintain a strict normal glycemic range. However, because the balance of glucose production and removal are unknown, and not considered in the simple measurement of blood glucose concentration, using blood glucose concentration as the diagnostic and insulin as the treatment often leads to wide swings in blood glucose concentration. Regrettably, despite diligent efforts on the part of clinicians attempting to maintain patients by dextrose drip and pushing insulin to normalize blood glucose concentration, the patient will be maintained at the perceived ideal blood glucose concentration range for only short periods of time. Additionally, the risk of hypoglycemia from too aggressive insulin therapy is also a serious risk and increased with intensive insulin therapy. Recognizing the difficulty of using dextrose and insulin therapy to maintain blood glucose concentration in injured and ill patients others have created computer-assisted record keeping devices to assist in therapy (59), while others have studied the benefits and liabilities of early versus late parenteral complement to enteral and oral nutritional support to achieve better patient outcomes and shorter hospitalization times (18). The methods fail for lack or knowing the underlying mechanisms of flux (metabolite appearance and disposal).

A better understanding of the pathophysiology resulting from the stress of critical illness is desired and, in fact, needed to better care for patients. Now, by means of our invention, using fractional GNG measurements a clinician shall be able to determine the exact nutritional and metabolic state of the patient, and therefore, be able to effectively intervene in illnesses such as, but not limited to, preterm infant care, complications from pregnancy requiring hospitalization, pre-operative surgery preparation and post-surgery monitoring, stroke, aneurism, terminal illness, urinary sepsis, cardiac failure (post-cardiac surgery), esophagectomy for carcinoma, subarachnoid hemorrhage, ileus, subdural hematoma, pulmonary sepsis, cardiac failure (post-myocardial infarction), respiratory failure (chronic obstructive pulmonary disease), oropharyngeal abscess, coronary bypass, resection of thoracic aneurysm, starvation, burns, severe acute respiratory syndrome (“SARS”) and potential epidemics and pandemics relating to influenza can be treated more precisely according to the individual nutritional needs based on the patients energy demands from their individual metabolic state.

The term “patient” often refers to an individual (human, other mammal or even other animals) suffering from injury or chronic disease. It can also refer to acutely or chronically stressed individuals such as premature infants, the chronically malnourished, underfed and physically exhausted athletes, soldiers and manual laborers, subjects in studies of pharmaceutical development, and many others. It can and here is intended to apply to individuals who also do not fit obvious or conventional notions of injured or ill patients, but can benefit from diagnostic, feeding or other treatments.

In fact, fractional GNG has already been measured in persons suffering many of the illnesses listed above; however, to date none have recognized that the nutritional needs of ill and injured patients could be met by targeting a constant range. The inventors, among others, have observed that a 12-hour fasts results in a fractional GNG of about 40%, while starvation over several days will drive fractional GNG above 90%. According to the invention, treatment of an ill or injured individual would involve negative feedback control of enteral nutrition and MCC infusion: response to high % GNG would be increasing enteral nutrition and MCC infusion, whereas low % GNG would mean over nutrition and the need to reduce feeding rate. A range of near 25% is generally an appropriately fed state, 3-4 hr after a balanced, CHO-containing meal. In healthy, uninjured individuals, a low level of fractional GNG, around 10% would be measured soon after they consumed a balanced, CHO-containing meal. A low fractional GNG of around 10% in a comatose individual, such as a TBI patient in an ICU, a GNG of 10% is unlikely, as has been observed by the inventors and other researchers, in studies to be published in the coming months, but would be indicative of over feeding and the need to reduce enteral feeding and MCC infusion until % GNG is in the 20-25% range, thus avoiding some of the consequences as described above. More typical of a TBI patient in the ICU would be % GNG>40%, thus requiring increased provision of enteral nutrition and vascular MCC infusion. In the case of a brain-injured person, the approach should be to maintain glycemia with both enteral nutrition and MCC infusion, the latter being important to supply cerebral nutrition and electrolytes to reduce cerebral swelling and minimizing hyperglycemia from dextrose.

In one embodiment, fractional GNG of 20-25% is aimed for, in another 15-35%. Regrettably, none of the current art has recognized that fractional GNG is the key biomarker of the pathophysiology related to critical illness. Regrettably also, none have used knowledge of fractional GNG to assess patient nutrient needs. We have devised such methods for intravenous, oral or gastric nutrient delivery to patients.

Large and extensive studies have been conducted to understand the benefits associated with nutritional support (18). Such studies have gone to some lengths to understand the patient's nutritional needs, but they have not found a good biomarker to indicate if patients are well nourished, overfed or underfed. Without the underlying metabolic state of the patient it is impossible to know what the exact nutritional needs are of that patient. Therefore, despite studying over 5000 patients, the above study was unable to determine a clear advantage to early parenteral nutrition to complete the enteral nutrition. They did, however identify negative consequences from overfeeding and underfeeding, but it is not clear that they are able to ascertain the precise nutritional status of their patents.

Some studies (65) have used indirect calorimetry in order to determine the exact energy expenditure over a 24 hr period and then administer 100% of the nutrients required to meet the energy expenditure of the individual patient. However, a close evaluation of their data reveals the percent contribution of glucose from gluconeogenesis indicates their patients were overfed. Despite the attempt to measure energy expenditure and deliver 100% of needed nutrients enterally, they inadvertently overfed their patients. Overfeeding like underfeeding, of hospitalized patients can result in serious negative consequences including infection, prolonged ventilation, metabolic disturbances (hyperglycemia, dyslipidemia, liver dysfunction), morbidity and mortality (50).

Some Other Applications

Already described are patient treatments following trauma and chronic illness. The invention also includes methods for managing those extreme and other cases and instances when assessment of BES, diagnosis and treatment are appropriate. Such examples include, but are not limited to assessing BES of patients or others before and after surgery, before and after drug treatment or dietary intervention, or any situation in which knowing, or standardizing BES is essential for determining outcome of any treatment, or establishing the effect of said treatment on humans or other mammals.

An example of using the new invention to set the BES background in which to evaluate safety, efficacy and functionality in the process of drug development. Drug development is a term used to describe the process of bringing a drug to market that includes pre-clinical research including animal studies, and human clinical trials, potentially leading to regulatory approval. In well-fed individuals % GNG can be as low as 10%, whereas after several days in the ICU % GNG could be 70% in TBI patients. Given this 7-fold range in GNG flux, pharmaceutical manufacturers with drugs that can affect metabolic flux rates several-fold would have a difficult time demonstrating effectiveness of their new drug. Therefore, with the present invention of being able to determine, and nourish individuals to the point of controlling GNG and establishing a stable background in which to evaluate effectiveness of a new drug, the patient treatments could be optimized. Also, costs associated with testing for the effectiveness of new drugs could be minimized.

Additionally, the application of % GNG may also improve dose response and efficacy for already established drugs or for new uses for drugs already on the market. For example, the commonly used drug Decadron (Dexamethasone) may have a new application in post-surgery applications for inflammation. However, it is anticipated that Decadron will affect the metabolic function of the patient. This augmented metabolic function might cause the patient to become catabolic simply from the administration of the drug and thus obviate the desired anti-inflammation characteristics of the drug by causing an undesirable side effect. If this action were to happen, the application for the drug might be interpreted to cause the patient to have a poor outcome. However, the outcome might be enhanced by proper nourishment using % GNG as a diagnostic. Under an appropriately nourished state, the administration of Decadron could minimize inflammation, leading to desired affect of administration of the drug and potentially a better overall outcome for the patient.

Determination of % GNG and the Timing, Type and Amount of Nutrient Delivery

Fractional gluconeogenesis (% GNG) will typically be determined on patients in the morning so that the Part 1 measurement can be made, interpreted in Part 2, and the target GNG or % GNG achieved during the work day. By this schedule, it can be anticipated that GNG be determined 3 times during the day, ideally morning, noon and evening. The morning measurement will provide important information on the patient's nutritional state through the evening and effectiveness on the ongoing, individual patient's needs for enteral nutrition and MCC infusion to achieve % GNG in the target range. Importantly, also, the morning measurement will inform clinicians to the need to adjust rates of enteral nutrition and MCC infusion. The noon, or early afternoon measurement will be important to monitor the individual patient's changing state, and to evaluate effectiveness of morning adjustments to achieve the target % GNG. And, the evening measurement will be important to establish stability of blood glucose concentration and % GNG in the patient during night hours when medical attention is typically less frequent.

Recovery from Illness and Trauma and Resumption of Oral Feeding

With the above described treatments (A-D) exquisite glycemic control shall be accomplished in comatose patients. However, procedures need to be in place for when patients recover consciousness sufficiently to allow the taking of some oral, including real-food, nutrition, but continue to require intravascular nutrient support. In all conditions, whether determined on patients after arising in the morning, or after a 12-hr fast, the target % GNG of 25% remains in place. For example, because most dietary energy might be consumed during awake hours, parenteral nutrition may be insufficient to prevent GNG from exceeding 25% of glucose Ra. Accordingly, food and parenteral nutrition would be given to achieve the target range of ˜20-25% GNG.

Care of Infants

The exhaustive body of literature cited above deals largely with the care of injured and ill adults. However, the CDC reports 500,000 pre-term births annually in the US. Pre-term is the birth of an infant prior to 37 weeks of gestation. Pre-term birth is the most frequent cause of infant death, and leading cause of neurological disabilities (49). Such children are in obvious need of nutritive support, whether or not surgery is required for survival, and the provision of nutritive support may avoid the development of conditions such as cerebral palsy, developmental delay, hearing impairment and other neurological disabilities and death. Although not highly developed in the literature, the provision of nutritive support to premature infants, and the monitoring of gluconeogenesis have been subjects of investigation (43, 77). Gluconeogenesis has been reported to be established 4-6 hr after birth in full-term children (43), and gluconeogenesis does respond to the availability nutritive support (77). Extremely low birth weight pre-term infants do present abnormalities in the ability to regulate GNG in response to nutrient supply (19), but nutritive support is none-the-less essential to the survival in such infants.

Care of Ill or Injured Mammals

Significant portions of the invention, principles, theory and practice would likely apply to the care of most mammals (11, 23) and others (37, 72, 84). A notable exception will apply to the care of ruminant mammals whose gut is evolved to digest fibrous plant materials such as cellulose to propionate (42), which is closely related to lactate (2-hydroxypropionate). Hence, in the case of ruminant mammals, the nutritional formulation could include 0-100% propionate.

Nutritive Formulations

Nutritive formulations to be given to patients after estimation of GNG (and in some cases, other biomarkers as well), has been discussed above, but will be discussed in more detail below.

Lactate-Based Formulations (Sanguisal-L)

In its simplest form, the MCC cocktail would be sodium-L-(+)-Lactate prepared by titrating L-(+)-Lactic acid with NaOH. The following describe such procedures: (24, 52, 55-57). Briefly, the MCC infusion cocktail is prepared by mixing concentrated (30-88%) L-(+)-lactic acid solution (e.g., Sigma-Aldrich or PCCA) in 2 N NaOH to pH 4.8. In the example provided, the starting point is a 30% stock lactic acid solution: 300 g 30% lactic acid stock solution is titrated with 133.3 g 2N NaOH and diluted to 1,000 ml with water. This will produce a 11.2% weight-by-volume (“w/v”) MCC cocktail (sodium-L-(+)-Lactate) with an osmolality approximating 2,000 mOsm/1. Depending on the stock lactic acid solution used, a NaOH titrating solution >2 N may be necessary to neutralize stock lactic acid without exceeding the intended volume. Regardless of the specifics of acid titration, a 1.72% Nat-lactate aqueous solution is isosmotic (308 mOsm/1); consequently, as initially mixed the above described MCC is far too concentrated to be given in a peripheral vein and will need to be diluted to less than 1,000 mOsm/1 (a 5.6% Nat-lactate solution). In a peripheral arm vein and a 5.0-5.6% Nat-lactate MCC should be given with normal (0.9%, 308 mOsm/1) saline or another isosmotic solution such as 5 mM glucose (dextrose) in water, commonly called D5W (see more below).

This isosmotic admixture of MCC and diluent at the MCC infusion site will be sufficient to maintain vessel patency and prevent phlebitis or hemolysis at the infusion site (56). In a large vessel a 5% Na⁺-lactate MCC cocktail could be given without expectation of hemolysis at the infusion site (57). Regardless of the dilution, the initial MCC solution delivery rate should be adjusted to deliver 10-50 (micro Moles) μMoles/kg/min, with maintenance infusion rate targeting blood lactate concentration of 3.5-4.5 mM, although higher levels (6 mM) have been used without ill effects (57, 71). Consistent with section methods described above, an infusion rate of 11 μMoles/kg/min would deliver the mass equivalent of 1.0 mg/kg/min of glucose, and infusion rate of 23 μMoles/kg/min of sodium lactate MCC would deliver the mass equivalent of 3 mg/kg/min glucose, and an infusion rate of 50 μMoles/kg/min would deliver the mass equivalent of 4.5 mg/kg/min of glucose. Ideally, the MCC is prepared from highest purity materials, is pathogen free, certified for human pharmaceutical use and is delivered into a large central vein, but peripheral vein can be used if administered with physiological saline to minimize osmolality and pH effects at the infusion site that might provoke phlebitis of hemolysis.

In another version of the simplest form, the MCC cocktail would be sodium-L-(+)-Lactate prepared from the dry, powdered salt in deionized water to the concentration intended [e.g., for an isosmotic solution: 154 mM lactate (plus 154 mM Na⁺) total osmolarity 308 mOsm/1], and infused in the above-stated amounts to raise arterial [lactate] to the intended levels.

In the preferred form of the simplest iteration, the basic sodium-L-(+)-Lactate cocktail would be amended to include other lactate salts as exist in the plasma of healthy humans. Sodium ion (Na⁺) is the main cation in plasma, normally 145 mM, and values for K⁺, Ca⁺⁺, and Mg⁺⁺ are, respectively, 4, 2.5 and 1.5 mM. Hence, a mixture of inorganic lactate salts comprised of Na⁺-, K⁺-, Ca⁺⁺-, and Mg⁺⁺-lactate would be combined in the ratio of 144, 4, 2.5, and 1.5. In this embodiment of invention, the main anion would be lactate, but phosphates are important ions in energy metabolism and would be added in the form of 1 mM NaH₂PO₄ ⁻ . Because Na⁺, K⁺, Ca⁺⁺, Mg⁺⁺, and H₂PO₄ ⁻ are present in the plasma of healthy individuals at levels of 145, 4, 2.5, 1.5, and 1.0 milliequivalent per liter (mEq/1) (53). This particular embodiment of MCC could be termed “Sanguisal” from the Latin words for blood (sanguis) and salt. To reiterate from above, the provision of sodium and other cations as a means to deliver lactate anions in an MCC has the advantage of reducing brain swelling following TBI (15) as well as providing nutritive support to intensive care patients following trauma (70).

Pyruvate-Based Formulations (Sanguisal-P)

As an alternative to Sanguisal-L that uses lactate as the major anion (vide supra), Sanguisal-P will involve the use of pyruvate (P) as the major anion, while at the same time maintaining the above-stated levels of cations {Na⁺, K⁺, Ca⁺⁺, Mg⁺⁺, and H₂PO₄ ⁻ as are present in the plasma of healthy individuals: 145, 4, 2.5, 1.5, and 1.0 mEq/1}. Like its counterpart lactate, pyruvate is the precursor to lactate in glycolysis. Further, pyruvate is an oxidizable fuel and GNG precursor whose metabolism may affect cell redox status if converted to lactate. Further, pyruvate possesses antioxidant properties (48). Although typically present in 1/10 or lesser concentration compared to lactate, pyruvate has been introduced into the systemic circulation of large mammals in which the circulation has been interrupted to mimic cardiac arrest (61-63, 68). In such cases 100% pyruvate infusion raises the circulating pyruvate level, but more so, the circulating lactate level achieving a circulating L/P of 2-3. None the less, because of its chemical structure, pyruvate has the advantage over lactate of serving as an antioxidant in the myocardium subjected to reperfusion injury, and, by extension exogenous pyruvate my also serve to scavenge free radicals in the brain after blood flow is interrupted. A problem with regard to the use of Sanguisal-P, in contrast to the Sanguisal-L form, is that in circulation pyruvate is rapidly converted to lactate due to the effects of lactate dehydrogenase in red blood cells and the lung parenchyma (41). Hence, for the antioxidant properties of pyruvate, the optimal site of Sanguisal-P infusion would be in the carotid artery or ascending aorta. Still, by the ability to infuse mixtures of Sanguisal-L and Sanguisal-P into the systemic circulation, ascending or carotid artery, the clinician would have the opportunity to affect redox status in an injured brain. However, because carotid or ascending catheterization is uncommon even in the ICU, systemic solutions of a very low L/P ratio (i.e., high P/L) such as infusion of 100% Sanguisal-P, or a mixture of Sanguisal-P/Sanguisal-L of 2.0 (L/P=¹/2 in the infusate), would serve to raise the arterial level of pyruvate relative to that of lactate.

In its simplest form, Sanguisal-P would be sodium-L-(+)-Pyruvate prepared by titrating L-(+)-Pyruvic acid with NaOH as described above for lactate (24, 52, 55-57). As with lactate (vide supra), the initial Na⁺-pyruvate infusion rate would deliver 11-50 (micro Moles) μMoles/kg/min, with maintenance infusion rate targeting blood lactate concentration of 3.5-4.5 mM, although higher levels (6 mM) have been used without ill effects (57, 71). Consistent with section methods described above, infusion rate of 11 μMoles/kg/min of sodium pyruvate MCC would deliver the mass equivalent of 1.0 mg/kg/min of glucose, an infusion rate of 23 μMoles/kg/min would deliver the mass equivalent of 3 mg/kg/min glucose, whereas an infusion rate of 50 μMoles/kg/min of sodium pyruvate MCC would deliver the mass equivalent of 4.5 mg/kg/min of glucose. Ideally, the Na⁺-pyruvate MCC is prepared from highest purity materials, is pathogen free, certified for human pharmaceutical use and is delivered into a large central vein, but peripheral vein can be used if administered with physiological saline to minimize osmolality and pH effects at the infusion site that might provoke phlebitis of hemolysis.

In another version of the simplest form, the MCC cocktail would be sodium-L-(+)-Pyruvate prepared from the dry, powdered salt in deionized water to the concentration intended, and infused in the above-stated amounts to raise arterial [lactate] to the intended levels. To reiterate, manufacturing and storing pyruvate-containing formulations such as Sanguisal P and Sanguisal L-P mixtures should ve anhydrous. Pure sterile water can be added immediately before delivery to avoid pyruvate degradation and accumulation of undesired pyruvate degradation products.

In the preferred form of the simplest iteration, the basic sodium-L-(+)-Pyruvate cocktail would be amended to include other pyruvate salts as exist in the plasma of healthy humans. Sodium ion (Na⁺) is the main cation in plasma, normally 145 mM, and values for K⁺, Ca⁺⁺, and Mg⁺⁺ are, respectively, 4, 2.5 and 1.5 mM. Hence, a mixture of inorganic lactate salts comprised of Na⁺-, K⁺-, Ca⁺⁺-, and Mg⁺⁺-lactate would be combined in the ratio of 144, 4, 2.5, and 1.5. In this embodiment of invention, the main anion would be pyruvate, but phosphates are important ions in energy metabolism and could be added in the form of 1 mM NaH₂PO₄ ⁻ . Because Na⁺, K⁺, Ca⁺⁺, Mg⁺⁺, and H₂PO₄ ⁻ are present in the plasma of healthy individuals at levels of 145, 4, 2.5, 1.5, and 1.0 milliequivalent per liter (mEq/1, this particular embodiment of MCC could be termed “Sanguisal” from the Latin words for blood (sanguis) and salt (53); in this case Sanguisal-P (for pyruvate). To reiterate from above, the provision of pyruvate and other cations as a means to deliver lactate anions in an MCC has the advantage of reducing brain swelling following TBI, as has been observed by the inventors and other researchers in studies to be published in the coming months, see also (15). The invention can also provides nutritive support to intensive care unit patients following trauma (70), and acting as a reactive oxygen species (“ROS”) scavenger (48).

In this preferred form, Sanguisal-P would be prepared from the dry, powdered pyruvate salts (Na⁺, K⁺, Ca⁺⁺, Mg⁺⁺, and H₂PO₄ ⁻ ) in the ratios of 145:4:2.5:1.5:1.0 in sterile deionized water to an anion concentration of 154 milliequivalent per liter (mEq/1), and infused in the above-stated amounts to raise arterial [pyruvate] to 1-2 mM and an arterial [lactate] in the intended range.

Lactate and Pyruvate Combination-Based Formulations (Sanguisal-L/P)

Isosmotic (154 mM) mixtures of Sanguisal-L and -P may be mixed and used to change the circulating L/P. Infusions of 2N Na⁺-Pyruvate into swine were observed to raise arterial [pyruvate] to 3.5 mM and [lactate] to 8 mM for an L/P in the range of 2-3 (68). If an arterial L/P of 10-11 is typical of healthy resting humans (36), then infusing a Sanguisal mix of 2 parts Sanguisal-P to 1 Part Sanguisal-L may reduce an elevated systemic L/P to that seen in healthy individuals. Then, by observation, the clinician has the ability to lower the circulating L/P by lowering the L/P of the Sanguisal mix given. Conversely, the clinician has the ability to raise the circulating L/P by increasing the L/P of the Sanguisal mix given. In summary, Sanguisal (S) mixes of 100% S-Pyruvate to 100% S-Lactate may be used to provide nutritive support to the injured brain and other injured or non-injured tissues, provide a gluconeogenic precursor, and scavenge ROS in all tissues perfused.

With regard to the infusion of Sanguisal-P, one may logically ask: “why is the resulting arterial [lactate] monitored?” There are practical as well as scientific reasons for this. From the practical standpoint, rapid lactate, but not pyruvate analyzers are available. And scientifically, lactate is the preferred monocarboxylate compound (MCC) in nature: the L/P in arterial blood of healthy individuals is minimally 10, and rises more than an order of magnitude in normal physiology. Secondly, pyruvate is rapidly converted to lactate in the blood by the action of lactic dehydrogenase in erythrocytes (RBCs) in the blood (69) and the lung parenchyma (41), and lactate, not pyruvate, it the major fuel source and GNG precursor (see above).

Regardless of whether Sanguisal-L, -P or -L/-P mixtures are administered, the clinician will monitor % GNG and titrate the Sanguisal infusion rate with the target to achieving approximate estimates of GNG between 15-30%.

Lactate Esters as MCCs

As described herein, Sanguisal-L and -P are inorganic salt-based means to deliver nutritive support. However, it is possible to deliver lactate and other nutritive compounds (pyruvate and acetate) by other means, including esters. Arginyl lactate (U.S. Pat. No. 5,420,107) has been extensively used as an (enteral) amendment to sports drinks to provide energy and blood buffering (1, 25). Arginyl lactate is formed by the electrostatic binding of lactate from lactic acid and the basic (zwitterion) amino acid arginine under basic conditions. These individual units dissociate spontaneously at neutral pH as exists in human plasma. The components of arginyl lactate (arginine and lactate) are benign and efficacious in human blood.

Similarly, the lactate thiolester formed from the combination of lactate and N-acetylcysteine (called “LNACE”, see, for example, U.S. Pat. No. 6,482,853) has been proposed as an amendment to sports drinks to provide energy and blood buffering. Like arginyl lactate, LNACE is yet another platform for parenteral nutrition of an ill or injured patient.

Still another means to deliver parenteral nutrition of an ill or injured patient is glycerol tri-lactate (called “GTL”, see, for example, U.S. Pat. No. 6,743,821). Glycerol tri-lactate is formed by the esterification of glycerol by lactic acid by means of organic or enzymatically catalyzed processes (see, for example, U.S. Pat. No. 6,743,821). These individual units rapidly dissociate because of the lipases and esterases in human plasma. The components of GTL (glycerol and lactate) are benign and efficacious in human blood. Glycerol has been used as a plasma expander (76) and gluconeogenic precursor (73). In terms of nutrient delivery, GTL is preferred over sodium- and other inorganic salts of lactate because more lactate is carried, no sodium load is incurred, and because the glycerol carrier is efficacious.

Still another means to deliver parenteral nutrition of an ill or injured patient is glycerol tri-acetate (called “GTA”, see, for example, U.S. Pat. No. 6,743,821), or acetin. Acetate is another body, although not brain, fuel energy source.

Lactate, Pyruvate and Dextrose Combination-Based Formulations (Sanguisal-L/P/D)

State of the art is to provide parenteral nutritive support to patients using 5% dextrose (D5W, glucose in water, vide supra). Because glucose (dextrose) has a molecular weight of 180, osmolality of D5W is 278 mM, which in the low range of normal plasma osmolality (275-310 mEq/1). Even though the glucose concentration in D5W is 50 times greater than homeostatic in plasma, in terms of its isosmotic effect with glucose alone being the only solute, D5W is isosmotic. Mixing equal isosmotic solutions such as equal volumes of 154 mM Sanguisal-L and D5W glucose will produce an osmolality in the high end of the normal range. As noted earlier, this slightly elevated osmolality because of sodium content will draw fluid from tissues into the vascular compartment, thus mitigating swelling due to injury (15).

Lactate, Pyruvate, and Amino Acid Combination-Based Formulations (Sanguisal-L/P/A)

Parenteral nutrition is provided to hasten nutrient delivery or gastrointestinal and other conditions exist to limit the enteral delivery of nutrients. The above-identified Sanguisal formulations are all carbohydrate (CHO)-based and can be used and adjusted to nourish the injured brain and other organs. In vivo, energy balance and nitrogen balance interact, the RDA for amino acid and protein intake being 0.8 g/kg body weight/day (8, 51), with the assumption being that the diet supplies sufficient energy to maintain energy balance. Although the latter assumption is seldom recognized with athletes taking upwards of 2 g/lb/body weight (60), even very high protein diets that are accompanied by a very high nitrogen load, will lack energy to maintain a person in nitrogen balance. Accordingly, in attempts to maintain nitrogen balance and body mass in injured and ill patients, amino acid and protein supplementation to the extent of 50% above the RDA for amino acids and proteins on the background of adequate energy supply is deemed prudent (82).

Commercially available parenteral amino acid solutions contain essential and non-essential amino acids. In contemporary literature, investigators have evaluated effects of emphasizing particular amino acids, and types of amino acids including: glutamine, arginine, cysteine, taurine, and branched chain amino acids (“BCAA”, leucine, isoleucine, and valine, particularly leucine). At present it is clear that parenteral solutions containing mixes of essential and non-essential amino acids are safe and efficacious, being part of routine parenteral nutrition. Such solutions are typically hyperosmotic, but less than 1,000 mOsm/1. As such, current art allows that infusions of Sanguisal-L, Sanguisal-P, or mixes of Sanguisal (L/P), could be augmented by infusions of amino acid parenteral solutions delivering 1.0-1.2 g nitrogen/kg body weight/day.

Lactate, Pyruvate, Dextrose and Amino Acid Combination-Based Formulations (Sanguisal-L/P/D/A)

When % GNG is unknown, with the assumption that blood glucose can be monitored in real time, a clinician can provide parenteral and enteral nutrition as described above. In the event of hepatic or renal failure, and consequent limitations in a patient's ability to clear sodium or regulate glycemia by means of providing GNG precursors, a clinician may moderate the course of providing lactate- and, or, pyruvate-based MCCs, and instead supplement the patient with D5W, in extreme hypoglycemia, D10W (5 mM glucose (dextrose)).

Adding D₂O to Sanguisal Formulations

For assessment of GNG using the D₂O method, first responders will need to take a first (“background”) blood sample before the injection of D₂O. As noted above, the 0.3 to 0.5% D₂O abundance necessary to estimate GNG from the penta-acetate derivative of glucose and GC/MS could be obtained by a bolus of D₂O. However, also as noted above, the 0.3 to 0.5% abundance of D₂O could be maintained over days and weeks by adding D₂O to all infusates given to TBI and other injured and ill patients. As Sanguisal solutions will be given to provide parenteral nutrition and maintain glycemia, as a preferred form, D₂O could be to make Sanguisal solutions 0.3 to 0.5% D₂O. Another preferred form of D₂O could be to make common intravenous saline solutions 0.3 to 0.5% D₂O as the majority of the exogenous fluids delivered to an ill or injured patient comes form the intravenous (“i.v.”) saline solutions routinely used in the hospital. If the exogenous fluid load can be controlled by the clinician through use of the common i.v. saline solution, then the enrichment of body water by deuterium can also be controlled and therefore the measurement of % GNG can be made for the duration of the stay at the hospital as frequently as required by the attending clinician. For example, if 100% of the exogenous solution come from the i.v. saline solution and the i.v. solution is a 1 liter bag, the i.v. solution will have approximately 0.3 to 0.5 g of D₂O added. If enteral feeding, for example, contributes 25% of the exogenous fluids, then the D₂O saline solution could contain 25% more D₂O to accommodate for the increased ingestion of exogenous fluids. Therefore the saline solution would now contain approximately 0.375 to 0.625 g D₂O.

With regard to the present invention, the many features and advantages of the present invention are apparent from the written description, and thus, it is intended by the appended claims to cover all such features and advantages of the invention. Further, since numerous modifications and changes will readily occur to those skilled in the art, it is not desired to limit the invention to the exact construction and operation as illustrated and described. Hence, all suitable modifications and equivalents may be resorted to as falling within the scope of the invention.

Various elements of the invention are described as modules implemented as software on a general purpose computer and others as hardware elements. It should be apparent that in various embodiments of the invention, implementation of software can be executed by embedded hardware, or vice versa, or in some combination of software and hardware. Also, a computer may take the form of an integrated circuit, printed circuit board, handheld computer, or any general-purpose computer without limitation.

Part of the invention may be implemented by a general-purpose computer, embedded circuitry, or some combination of these. The software execution may be accomplished through the use of a program storage device readable by the computer and encoding a program of instructions executable by the computer for performing the operations described above. The program storage device may take the form of any memory known in the art or subsequently developed. The program of instructions may be object code, i.e., in binary form that is executable more-or-less directly by the computer; in source code that requires compilation or interpretation before execution; or in some intermediate form such as partially compiled code and/or a collection of executable library files. The precise forms of the program storage device and of the encoding of instructions are immaterial here.

The invention also contemplates use of computer networks known in the art, including but not limited to, intranets such as corporate networks, local and wide area networks, the Internet and the World Wide Web. Wire and wireless communication and communication protocols known in the art, such as, but not limited to, radio, infrared, Bluetooth, Ethernet and other wireless and wired networks, are also contemplated.

Preferred embodiments of flow direction between elements, looping and iteration are discussed, but alternative embodiments of these flows are contemplated by the invention. Any elements or other features described in the figures, even if not described in the specification, are supported in the figures so as to be enabling. All references cited here are incorporated in their entirety for all purposes.

REFERENCES

-   1. Azevedo J L, Tietz E, Two-Feathers T, Paull J, and Chapman K.     Lactate, fructose and glucose oxidation profiles in sports drinks     and the effect on exercise performance. PLoS One 2: e927, 2007. -   2. Bergman B C, Butterfield G E, Wolfel E E, Lopaschuk G D, Casazza     G A, Horning M A, and Brooks G A. Muscle net glucose uptake and     glucose kinetics after endurance training in men. Am J Physiol 277:     E81-92, 1999. -   3. Bergman B C, Horning M A, Casazza G A, Wolfel E E, Butterfield G     E, and Brooks G A. Endurance training increases gluconeogenesis     during rest and exercise in men. Am J Physiol Endocrinol Metab 278:     E244-251, 2000. -   4. Bergman B C, Wolfel E E, Butterfield G E, Lopaschuk G D, Casazza     G A, Horning M A, and Brooks G A. Active muscle and whole body     lactate kinetics after endurance training in men. Journal of applied     physiology 87: 1684-1696, 1999. -   5. Brooks G A. Cell-cell and intracellular lactate shuttles. Journal     of Physiology 587: 5591-5600, 2009. -   6. Brooks G A. Glycolytic end product and oxidative substrate during     sustained exercise in mammals—the “lactate shuttle. Comparative     Physiology and Biochemistry—Current Topics and Trends, Volume A,     Respiration—Metabolism—Circulation: 208-218, 1984. -   7. Brooks G A. Lactate Shuttles in Nature. Biochemical Society     Transactions 30: 258-264, 2002. -   8. Brooks G A, Butte N F, Rand W M, Flatt J P, and Caballero B.     Chronicle of the Institute of Medicine physical activity     recommendation: how a physical activity recommendation came to be     among dietary recommendations. Am J Clin Nutr 79: 921S-930S, 2004. -   9. Brooks G A, Butterfield G E, Wolfe R R, Groves B M, Mazzeo R S,     Sutton J R, Wolfel E E, and Reeves J T. Decreased reliance on     lactate during exercise after acclimatization to 4,300 m. Journal of     applied physiology 71: 333-341, 1991. -   10. Brooks G A, Butterfield G E, Wolfe R R, Groves B M, Mazzeo R S,     Sutton J R, Wolfel E E, and Reeves J T. Increased dependence on     blood glucose after acclimatization to 4,300 m. Journal of applied     physiology 70: 919-927, 1991. -   11. Brooks G A and Donovan C M. Effect of endurance training on     glucose kinetics during exercise. Am J Physiol 244: E505-512, 1983. -   12. Brooks G A, Fahey T D, and Baldwin K M. Exercise Physiology:     Human Bioenergetics and It's Applications. McGraw-Hill, 2004, p.     162-171, 753-756. -   13. Brooks G A, Wolfel E E, Butterfield G E, Cymerman A, Roberts A     C, Mazzeo R S, and Reeves J T. Poor relationship between arterial     [lactate] and leg net release during exercise at 4,300 m altitude.     Am J Physiol 275: R1192-1201, 1998. -   14. Brooks G A, Wolfel E E, Groves B M, Bender P R, Butterfield G E,     Cymerman A, Mazzeo R S, Sutton J R, Wolfe R R, and Reeves J T.     Muscle accounts for glucose disposal but not blood lactate     appearance during exercise after acclimatization to 4,300 m. Journal     of applied physiology 72: 2435-2445, 1992. -   15. Bullock R, Chesnut R M, Clifton G, Ghajar J, Marion D W, Narayan     R K, Newell D W, Pitts L H, Rosner M J, and Wilberger J W.     Guidelines for the management of severe head injury. Brain Trauma     Foundation. Eur J Emerg Med 3: 109-127, 1996. -   16. Cahill G J, Jr., Owen O E, and Morgan A P. The consumption of     fuels during prolonged starvation. Adv Enzyme Regul 6: 143-150,     1968. -   17. Cannon W B. The Wisdom of the Body. New York: Norton, 1932. -   18. Casaer M P, Hermans G, Wilmer A, and Van den Berghe G. Impact of     early parenteral nutrition completing enteral nutrition in adult     critically ill patients (EPaNIC trial): a study protocol and     statistical analysis plan for a randomized controlled trial. Trials     12: 21, 2011. -   19. Chacko S K, Ordonez J, Sauer P J, and Sunehag A L.     Gluconeogenesis is not regulated by either glucose or insulin in     extremely low birth weight infants receiving total parenteral     nutrition. J Pediatr 158: 891-896, 2011. -   20. Chacko S K, Sunehag A L, Sharma S, Sauer P J, and Haymond M W.     Measurement of gluconeogenesis using glucose fragments and mass     spectrometry after ingestion of deuterium oxide. Journal of applied     physiology 104: 944-951, 2008. -   21. Colberg S R, Casazza G A, Horning M A, and Brooks G A. Increased     dependence on blood glucose in smokers during rest and sustained     exercise. Journal of Applied Physiology 76: 26-32, 1994. -   22. Colberg S R, Casazza G A, Horning M A, and Brooks G A.     Metabolite and hormonal response in smokers during rest and     sustained exercise. Med Sci Sports Exerc 27: 1527-1534, 1995. -   23. Donovan C M and Brooks G A. Endurance training affects lactate     clearance, not lactate production. Am J Physiol 244: E83-92, 1983. -   24. Emhoff C A, Messonnier L A, Horning M A, Fattor J A, Carlson T     J, and Brooks G A. Gluconeogenesis and hepatic glycogenolysis during     exercise at the lactate threshold. Journal of Applied Physiology     114: 297-306, 2013. -   25. Fahey T D, Larsen J D, Brooks G A, Colvin W, Henderson S, and     Lary D. The effects of ingesting polylactate or glucose polymer     drinks during prolonged exercise. Int J Sport Nutr 1: 249-256, 1991. -   26. Friedlander A L, Casazza G A, Horning M A, Huie M J, and Brooks     G A. Training-induced alterations of glucose flux in men. Journal of     applied physiology 82: 1360-1369, 1997. -   27. Friedlander A L, Casazza G A, Horning M A, Huie M J, Piacentini     M F, Trimmer J K, and Brooks G A. Training-induced alterations of     carbohydrate metabolism in women: women respond differently from     men. Journal of applied physiology 85: 1175-1186, 1998. -   28. Glenn T C, Kelly D F, Boscardin W J, McArthur D L, Vespa P,     Oertel M, Hovda D A, Bergsneider M, Hillered L, and Martin N A.     Energy dysfunction as a predictor of outcome after moderate or     severe head injury: indices of oxygen, glucose, and lactate     metabolism. J Cereb Blood Flow Metab 23: 1239-1250, 2003. -   29. Griffiths R D. Too much of a good thing: the curse of     overfeeding. Crit Care 11: 176, 2007. -   30. Guo Z K, Lee W N, Katz J, and Bergner A E. Quantitation of     positional isomers of deuterium-labeled glucose by gas     chromatography/mass spectrometry. Anal Biochem 204: 273-282, 1992. -   31. Hachey D L, Wong W W, Boutton T W, and, and Klein P D. Isotope     ratio measurements in nutrition and biomedical research. Mass     Spectrom Rev 6: 289-328, 1987. -   32. Harris J A and Benedict F G. A Biometric Study of Human Basal     Metabolism. Proc Natl Acad Sci USA 4: 370-373, 1918. -   33. Hashimoto T, Hussien R, Cho H S, Kaufer D, and Brooks G A.     Evidence for the mitochondrial lactate oxidation complex in rat     neurons: demonstration of an essential component of brain lactate     shuttles. PLoS One 3: e2915, 2008. -   34. Haymond M W and Sunehag A L. The reciprocal pool model for the     measurement of gluconeogenesis by use of [U-(13)C]glucose. Am J     Physiol Endocrinol Metab 278: E140-145, 2000. -   35. Hellerstein M K, Neese R A, Linfoot P, Christiansen M, Turner S,     and Letscher A. Hepatic gluconeogenic fluxes and glycogen turnover     during fasting in humans. A stable isotope study. J Clin Invest 100:     1305-1319, 1997. -   36. Henderson G C, Horning M A, Wallis G A, and Brooks G A. Pyruvate     metabolism in working human skeletal muscle. Am J Physiol Endocrinol     Metab 292: E366, 2007. -   37. Hetenyi G, Jr. Correction for the metabolic exchange of 14C for     12C atoms in the pathway of gluconeogenesis in vivo. Fed Proc 41:     104-109, 1982. -   38. Hetenyi G, Jr. Gluconeogenesis in vivo. Am J Physiol 249:     R792-793, 1985. -   39. Huie M J, Casazza G A, Horning M A, and Brooks G A. Smoking     increases conversion of lactate to glucose during submaximal     exercise. Journal of applied physiology 80: 1554-1559, 1996. -   40. Jenssen T, Nurjhan N, Consoli A, and Gerich J E. Dose-response     effects of lactate infusions on gluconeogenesis from lactate in     normal man. Eur J Clin Invest 23: 448-454, 1993. -   41. Johnson M L, Hussien R, Horning M A, and Brooks G A.     Transpulmonary pyruvate kinetics. Am J Physiol Regul Integr Comp     Physiol 301: R769-774, 2011. -   42. Junghans P, Gors S, Lang I S, Steinhoff J, Hammon H M, and     Metges C C. A simplified mass isotopomer approach to estimate     gluconeogenesis rate in vivo using deuterium oxide. Rapid Commun     Mass Spectrom 24: 1287-1295, 2010. -   43. Kalhan S C, Parimi P, Van Beek R, Gilfillan C, Saker F, Gruca L,     and Sauer P J. Estimation of gluconeogenesis in newborn infants. Am     J Physiol Endocrinol Metab 281: E991-997, 2001. -   44. Landau B R. Quantifying the contribution of gluconeogenesis to     glucose production in fasted human subjects using stable isotopes.     Proc Nutr Soc 58: 963-972, 1999. -   45. Landau B R, Wahren J, Chandramouli V, Schumann W C, Ekberg K,     and Kalhan S C. Use of 2H2O for estimating rates of gluconeogenesis.     Application to the fasted state. J Clin Invest 95: 172-178, 1995. -   46. Lanza I R, Zhang S, Ward L E, Karakelides H, Raftery D, and Nair     K S. Quantitative metabolomics by H-NMR and LC-MS/MS confirms     altered metabolic pathways in diabetes. PLoS One 5: e10538, 2010. -   47. Loh N H W and Griffiths R D. The Curse of Overfeeding and the     Blight of Underfeeding: Springer New York, 2009. -   48. Mallet R T and Sun J. Antioxidant properties of myocardial     fuels. Mol Cell Biochem 253: 103-111, 2003. -   49. Mathews T J and MacDorman M F. Infant mortality statistics from     the 2007 period linked birth/infant death data set. Natl Vital Stat     Rep 59: 1-30, 2011. -   50. McClave S A, Lowen C C, Kleber M J, Nicholson J F, Jimmerson S     C, McConnell J W, and Jung L Y. Are patients fed appropriately     according to their caloric requirements? JPEN J Parenter Enteral     Nutr 22: 375-381, 1998. -   51. Medicine I O. DIETARY REFERENCE INTAKES: Energy, Carbohydrate,     Fiber, Fat, Fatty Acids, Cholesterol, Protein, and Amino Acids.     Washington, D.C.: The National Academies Press, 2005, p. 107-264. -   52. Messonnier A L, Emhoff C W, Fattor J A, Horning M A, T. J. C,     and Brooks G A. Lactate kinetics at the lactate threshold in trained     and untrained men. Journal of Applied Physiology 114, 2013. -   53. Messonnier L, Samb A, Tripette J, Gogh B D, Loko G, Sall N D,     Feasson L, Hue O, Lamothe S, Bogui P, and Connes P. Moderate     endurance exercise is not a risk for rhabdomyolysis or renal failure     in sickle cell trait carriers. Clin Hemorheol Microcirc 51: 193-202,     2012. -   54. Meyer C, Dostou J M, Welle S L, and Gerich J E. Role of human     liver, kidney, and skeletal muscle in postprandial glucose     homeostasis. Am J Physiol Endocrinol Metab 282: E419-427, 2002. -   55. Miller B F, Fattor J A, Jacobs K A, Horning M A, Navazio F,     Lindinger M I, and Brooks G A. Lactate and glucose interactions     during rest and exercise in men: effect of exogenous lactate     infusion. J Physiol 544: 963-975, 2002. -   56. Miller B F, Fattor J A, Jacobs K A, Horning M A, Suh S H,     Navazio F, and Brooks G A. Metabolic and cardiorespiratory responses     to “the lactate clamp”. Am J Physiol Endocrinol Metab 283: E889-898,     2002. -   57. Miller B F, Lindinger M I, Fattor J A, Jacobs K A, Leblanc P J,     Duong M, Heigenhauser G J, and Brooks G A. Hematological and     acid-base changes in men during prolonged exercise with and without     sodium-lactate infusion. Journal of applied physiology 98: 856-865,     2005. -   58. Neese R A, Schwarz J M, Faix D, Turner S, Letscher A, Vu D, and     Hellerstein M K. Gluconeogenesis and intrahepatic triose phosphate     flux in response to fasting or substrate loads. Application of the     mass isotopomer distribution analysis technique with testing of     assumptions and potential problems. J Biol Chem 270: 14452-14466,     1995. -   59. Peter J V, Moran J L, and Phillips-Hughes J. A metaanalysis of     treatment outcomes of early enteral versus early parenteral     nutrition in hospitalized patients. Crit Care Med 33: 213-220;     discussion 260-211, 2005. -   60. Phillips S M. Dietary protein requirements and adaptive     advantages in athletes. Br J Nutr 108 Suppl 2: S158-167, 2012. -   61. Ryou M G, Flaherty D C, Hoxha B, Gurji H, Sun J, Hodge L M,     Olivencia-Yurvati A H, and Mallet R T. Pyruvate-enriched     cardioplegia suppresses cardiopulmonary bypass-induced myocardial     inflammation. Ann Thorac Surg 90: 1529-1535, 2010. -   62. Ryou M G, Flaherty D C, Hoxha B, Sun J, Gurji H, Rodriguez S,     Bell G, Olivencia-Yurvati A H, and Mallet R T. Pyruvate-fortified     cardioplegia evokes myocardial erythropoietin signaling in swine     undergoing cardiopulmonary bypass. Am J Physiol Heart Circ Physiol     297: H1914-1922, 2009. -   63. Ryou M G, Liu R, Ren M, Sun J, Mallet R T, and Yang S H.     Pyruvate protects the brain against ischemia-reperfusion injury by     activating the erythropoietin signaling pathway. Stroke 43:     1101-1107, 2012. -   64. Schurr A. Lactate: a major and crucial player in normal function     of both muscle and brain. J Physiol 586: 2665-2666, 2008. -   65. Schwarz J M, Chiolero R, Revelly J P, Cayeux C, Schneiter P,     Jequier E, Chen T, and Tappy L. Effects of enteral carbohydrates on     de novo lipogenesis in critically ill patients. Am J C M Nutr 72:     940-945, 2000. -   66. Scrimgeour C M, Rollo M M, Mudambo S M, Handley L L, and Prosser     S J. A simplified method for deuterium/hydrogen isotope ratio     measurements on water samples of biological origin. Biol Mass     Spectrom 22: 383-387, 1993. -   67. Selye H. Stress and the general adaptation syndrome. Br Med J 1:     1383-1392, 1950. -   68. Sharma A B, Barlow M A, Yang S H, Simpkins J W, and Mallet R T.     Pyruvate enhances neurological recovery following cardiopulmonary     arrest and resuscitation. Resuscitation 76: 108-119, 2008. -   69. Sharma A B, Knott E M, Bi J, Martinez R R, Sun J, and Mallet     R T. Pyruvate improves cardiac electromechanical and metabolic     recovery from cardiopulmonary arrest and resuscitation.     Resuscitation 66: 71-81, 2005. -   70. Slone D S. Nutritional support of the critically ill and injured     patient. Crit Care Clin 20: 135-157, 2004. -   71. Smith D, Pernet A, Hallett W A, Bingham E, Marsden P K, and     Amiel S A. Lactate: a preferred fuel for human brain metabolism in     vivo. J Cereb Blood Flow Metab 23: 658-664, 2003. -   72. Tayek J A and Katz J. Glucose production, recycling, and     gluconeogenesis in normals and diabetics: a mass isotopomer     [U-13C]glucose study. Am J Physiol 270: E709-717, 1996. -   73. Trimmer J K, Casazza G A, Horning M A, and Brooks G A.     Autoregulation of glucose production in men with a glycerol load     during rest and exercise. Am J Physiol Endocrinol Metab 280:     E657-668, 2001. -   74. Trimmer J K, Schwarz J M, Casazza G A, Horning M A, Rodriguez N,     and Brooks G A. Measurement of gluconeogenesis in exercising men by     mass isotopomer distribution analysis. Journal of applied physiology     93: 233-241, 2002. -   75. Umpierrez G E, Hellman R, Korytkowski M T, Kosiborod M, Maynard     G A, Montori V M, Seley J J, and Van den Berghe G. Management of     hyperglycemia in hospitalized patients in non-critical care setting:     an endocrine society clinical practice guideline. J Clin Endocrinol     Metab 97: 16-38, 2012. -   76. van Rosendal S P, Osborne M A, Fassett R G, and Coombes J S.     Guidelines for glycerol use in hyperhydration and rehydration     associated with exercise. Sports Med 40: 113-129, 2010. -   77. Verbruggen S C, de Betue C T, Schierbeek H, Chacko S, van     Adrichem L N, Verhoeven J, van Goudoever J B, and Joosten K F.     Reducing glucose infusion safely prevents hyperglycemia in     post-surgical children. Clin Nutr 30: 786-792, 2011. -   78. Vespa P, Boonyaputthikul R, McArthur D L, Miller C, Etchepare M,     Bergsneider M, Glenn T, Martin N, and Hovda D. Intensive insulin     therapy reduces microdialysis glucose values without altering     glucose utilization or improving the lactate/pyruvate ratio after     traumatic brain injury. Crit Care Med 34: 850-856, 2006. -   79. Widmaier E P, Raff H, and Strang K T. Vander's Human Physiology.     (12th ed.). New York: McGraw-Hill, 2011, p. 528-530, Back inside     cover. -   80. Wolfe R R. Radioactive and Stable Isotope Tracers in     Biomedicine: Principles and Practice of Kinetic Analysis. New York:     Wiley-Liss, 1982, p. 81-83, 142-143. -   81. Yang D, Diraison F, Beylot M, Brunengraber D Z, Samols M A,     Anderson V E, and Brunengraber H. Assay of low deuterium enrichment     of water by isotopic exchange with [U-13C3]acetone and gas     chromatography-mass spectrometry. Anal Biochem 258: 315-321, 1998. -   82. Yarandi S S, Zhao V M, Hebbar G, and Ziegler T R. Amino acid     composition in parenteral nutrition: what is the evidence? Curr Opin     Clin Nutr Metab Care 14: 75-82, 2011. -   83. Zhang Y and Szolovits P. Patient-specific learning in real time     for adaptive monitoring in critical care. J Biomed Inform 41:     452-460, 2008. -   84. Zilversmit D B, Entenman C, Fishier M C, and Chaikoff I L. The     Turnover Rate of Phospholipids in the Plasma of the Dog as Measured     with Radioactive Phosphorus. J Gen Physiol 26: 333-340, 1943. 

What is claimed is:
 1. A method of addressing the nutritional status of a patient, the method comprising: (a) administering a molecular label; (b) taking a blood sample; (c) measuring incorporation of the molecular label into glucose in order to obtain a value or range of values for fractional gluconeogenesis; and (d) administering a formulation wherein the formulation is administered or increased if the fractional gluconeogenesis is above 20-25%.
 2. The method of claim 1 wherein (b) and (c) are done on a periodic basis in order to provide an ongoing estimate of fractional gluconeogenesis.
 3. The method of claim 1 wherein an initial bolus of the molecular label is given to the patient.
 4. The method of claim 1 wherein the initial bolus labels less than 1% of the patient's body water.
 5. The method of claim 1 wherein the molecular label is deuterium.
 6. The method of claim 1 wherein the formulation has zero or close to zero nutritional content to accommodate a patient that is adequately fed.
 7. The method of claim 1 wherein the formulation comprises a gluconeogenic precursor or a monocarboxylic compound or both.
 8. The method of claim 1 wherein the formulation further comprises one or more of the following: Na⁺, K⁺, Ca⁺⁺, Mg⁺⁺, H₂PO₄ ⁻ or HPO₄ ⁻⁻ .
 9. The method of claim 1 wherein the formulation has an osmolality of less than 1000 mOsm.
 10. The method of claim 1 wherein the formulation further comprises lactate or pyruvate or both.
 11. The method of claim 1 wherein the formulation further comprises a gluconeogenic precursor or a monocarboxylic compound that is not lactate.
 12. The method of claim 1 wherein the formulation further comprises an amino acid.
 13. The method of claim 1 wherein the formulation further comprises one or more of the following: glycerol, glycerol tri-lactate or arginyl lactate.
 14. The method of claim 1 wherein the formulation is administered at a rate of 3 mg/kg/min, where kg is kg of patient body weight and 3 mg is the amount of gluconeogenic precursor or monocarboxylic compound in the formulation.
 15. The method of claim 1 wherein the formulation is administered at a rate of 50 micromoles/kg/min, where kg is kg of patient body weight and 50 micromoles is the amount of gluconeogenic precursor or monocarboxylic compound in the formulation.
 16. The method of claim 1 wherein the method targets the fractional gluconeogenesis to be 20-25%.
 17. The method of claim 1 wherein the label is in the formulation.
 18. A method of addressing the nutritional status of a patient, the method comprising: (a) administering a molecular label; (b) taking a blood sample; (c) measuring incorporation of the molecular label into glucose in order to obtain a value or range of values for gluconeogenesis and a value or range of values for gluconeogenesis plus glycogenolysis; (d) using the value or range of values in (c) for guidance, administering a formulation wherein the formulation is administered or increased if the fractional gluconeogenesis is above 15-30%.
 19. The method of claim 18 wherein one or more of (a)-(d) are done on a periodic basis in order to provide an ongoing estimate of fractional gluconeogenesis.
 20. The method of claim 18 wherein an initial bolus of molecular label is given to the patient.
 21. The method of claim 18 wherein the initial bolus labels less than 1% of the patient's body water.
 22. The method of claim 18 wherein the molecular label is deuterium.
 23. The method of claim 18 wherein the formulation has zero or close to zero nutritional content to accommodate a patient that is adequately fed.
 24. The method of claim 18 wherein the formulation comprises a gluconeogenic precursor or a monocarboxylic compound or both.
 25. The method of claim 18 wherein the formulation further comprises one or more of the following: Na⁺, K⁺, Ca⁺⁺, Mg⁺⁺, H₂PO₄ ⁻ or HPO₄ ⁻⁻ .
 26. The method of claim 18 wherein the formulation has an osmolality of less than 1000 mOsm.
 27. The method of claim 18 wherein the formulation further comprises lactate or pyruvate or both.
 28. The method of claim 18 wherein the formulation further comprises a gluconeogenic precursor or a monocarboxylic compound that is not lactate.
 29. The method of claim 18 wherein the formulation further comprises an amino acid.
 30. The method of claim 18 wherein the formulation further comprises one or more of the following: glycerol, glycerol tri-lactate or arginyl lactate.
 31. The method of claim 18 wherein the formulation is administered at a rate of 3 mg/kg/min, where kg is kg of patient body weight and 3 mg is the amount of gluconeogenic precursor or monocarboxylic compound in the formulation.
 32. The method of claim 18 wherein the formulation is administered at a rate of 50 micromoles/kg/min, where kg is kg of patient body weight and 50 micromoles is the amount of gluconeogenic precursor or monocarboxylic compound in the formulation.
 33. The method of claim 18 wherein the method targets the fractional gluconeogenesis to be about 15-30%.
 34. The method of claim 18 wherein the label is in the formulation. 